Clinical Bacteriology Lecture - Microbiology PDF

Summary

This document is a lecture note on clinical bacteriology, covering topics like microbiology, introduction to bacteriology, definitions of terms, and branches of microbiology. It includes information about diseases, related infections, and the various groups of microbes.

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CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

INTRODUCTION TO BACTERIOLOGY DEFINITION OF TERMS

PATHOGENS: disease-causing
MICROBIOLOGY
microorganism such as bacteria, fungi,
protozoans, and viruses
- includes the study of certain
non-living entities as well as OPPORTUNISTIC
TRUE PATHOGEN
PATHOGEN
certain living organisms.
Collectively, these non-living organism that will organisms that will
entities and living organisms are cause disease in a cause disease in an
called microbes. healthy host immunocompromised
- a branch of biology which deals host
with the study of living organisms PATHOGENICITY: ability of an organism
that are too small to be seen by to cause disease in a host organism
the naked eye VIRULENCE: the degree of
pathogenicity; the power by which a
BRANCHES OF MICROBIOLOGY pathogen can cause a severe disease
PATHOGENIC
BASIC DETERMINANTS/VIRULENCE FACTORS:
By organism By process Disease related
any genetic, biochemical or structural
features that enable a pathogen to cause
Bacteriology Microbial Immunology disease in a host organism
Phycology metabolism Epidemiology INFECTION: the entry, invasion and
Mycology Microbial Etiology multiplication of pathogens in or on to
Virology genetics the host body system which results to
Parasitology subsequent tissue injury and progress to
Protozoology overt disease
APPLIED A. Based on Source of Pathogen
Disease Environmentally ENDOGENOUS EXOGENOUS
Industrial
related related INFECTION: infection INFECTION: infection
Infection
arising from colonizing arising from invading
Environmental Food and
control beverage tech flora pathogen from the
microbiology
Chemotherapy Pharmaceutical external environment
microbiology
B. Based on Clinical Onset of Signs and
Genetic
engineering
Symptoms
ACUTE INFECTION: CHRONIC INFECTION:
rapid/sudden onset of gradual onset of signs
4 GROUPS OF MICROBES
signs and symptoms and symptoms that
VIRUS: Very simple microbes, consisting which are usually are usually mild to
of nucleic acid, a few proteins, and (in severe to fatal that moderate that may
some) a lipid envelope may lead to death progress to long
FUNGI: Heterotrophic eukaryotes that standing infection
obtain nutrients through absorption C. Based on Etiologic/Causative Agent
PARASITES: Eukaryotic organisms that
live at the expense of their hosts exist as NOSOCOMIAL ZOONOTIC INFECTION
unicellular organisms of microscopic size INFECTION: acquired (ZOONOSIS): animal
whereas others are multicellular during hospitalization disease which can
organisms spread to humans;
BACTERIA: Prokaryotic, unicellular animal-acquired
organisms that lack a nuclear membrane infection
and true nucleus

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

D. Based on Clinical Manifestations rabies, anthrax,
dysentery, smallpox,
SUBCLINICAL/ CLINICAL/ ergotism, botulism,
ASYMPTOMATIC/ NON SYMPTOMATIC/ measles, typhoid
APPARENT: no APPARENT: associated fever, typhus fever,
obvious appearance of with presence of overt diphtheria, and
signs and symptoms signs and symptoms of syphilis
and the person is the disease - First appeared in
unaware of the Europe
infection - Was carried by the
Native Americans
DISEASE: an altered health state in an
who were brought
infected host
in Portugal by
→ INFECTIOUS DISEASE: caused by Christopher
a pathogen which invades body SYPHILIS Columbus
tissues and causes damage 1493 (Treponema - Neapolitan Disease
→ COMMUNICABLE DISEASE: pallidum) (French)
capable of spreading from person - French or Spanish
to person Disease (Italian)
→ SYMPTOMS: any subjective - French pox
evidence of disease (English)
- Spanish, German,
○ E.g. headache, dizziness,
Polish and Turkish
etc. pocks
→ SIGNS: readily observable
evidence of disease The infection was
1530
NORMAL FLORA: Bacteria that are in or named “Syphilis”
on different sites of the body that usually PIONEERS IN MICROBIOLOGY
do not harm the host unless the host
- First person to see live bacteria
defense is compromised
and protozoa
COLONIZATION: the establishment of - “Father of Microbiology,
substantial number of microorganisms Bacteriology, Protozoology”
usually in the skin or mucosa but there’s - He ground tiny glass lenses,
no penetration of tissues which he mounted in small metal
Anton Van
frames, thus creating what today
EARLIEST KNOWN INFECTIOUS DISEASES Leeuwenhoek
are known as single lens
- Fatal epidemic (1632-1723)
microscopes or simple
disease caused by a microscopes
bacteria called - He observed various tiny living
PESTILENCE
3180 BC Yersinia pestis – creatures, which he called
and PLAGUE
BLACK DEATH “animalcules” (bacteria and
- The first recorded protozoa)
epidemic
- Demonstrated that different
near the end of the types of microbes produce
Trojan war, the different fermentation products
Around BUBONIC
Greek army was - Disproved theory of
900 BC PLAGUE
decimated by this spontaneous
epidemic Louis Pasteur generation/Abiogenesis
EBERS describing epidemic (1822-1895) − Life can arise spontaneously
1500 BC from non-living materials
PAPYRUS fevers
- He introduced the terms
1122 BC SMALLPOX occurred in China “aerobes” (requires oxygen) and
“anaerobes” (does not requires
- occurred in Rome
oxygen)
790, 710, EPIDEMICS OF and in Greece
and 640 BC PLAGUE around 430 BC PASTEURIZATION
- Early accounts of - Heating liquids to 63–65°C for 30 minutes or

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

73 75°C for 15 seconds Semmelweis - showed quite clearly that
- Type of sterilization. Only kills pathogen women became infected in the
maternity ward after
GERM THEORY DISEASE
examinations by physicians
- Specific microbes cause specific infectious diseases
coming directly from the autopsy
- Developed vaccines to prevent chicken cholera,
room
anthrax and swine erysipelas
- First to introduce aseptic
- Made many significant
techniques aimed at reducing
contributions to the germ theory Joseph Lister
microbes in a medical setting and
of disease
preventing wound infections
- Discovered that B. anthracis
produces spores, capable of KEY DEVELOPMENTAL
resisting adverse conditions PERIOD
SCIENTIST/S NOTES
- Developed methods of fixing,
Robert Koch Publication of the first
staining, and photographing
(1843-1910) 1665 Robert Hooke description of
bacteria, methods of cultivating
bacteria on solid media microbes
- Discovered the bacterium (M. Anton van Observation of “little
tuberculosis) that causes 1667
Leeuwenhoek animals”
tuberculosis and the bacterium
(Vibrio cholerae) that causes Smallpox Vaccination
cholera 1796 Edward Jenner – first scientific
validation
Koch’s Postulate
Advocating
Ignaz handwashing in the
1850
Semmelweis prevention of the
spread of disease
Spontaneous
1861
generation disproved

Louis Pasteur Publication of the
paper supporting the
1862
germ theory of
disease
Practice of Antiseptic
1867 Joseph Lister
THE DISCOVERY OF SPORES AND STERILIZATION Surgery

- Provided the initial evidence Discovery of Bacillus
that some of the microbes in dust anthracis which
1876
and air have very high heat became the first proof
John Tyndall resistance and that particularly of germ theory
vigorous treatment is required to Robert Koch Utilization of solid
destroy them 1881 culture media for
- Developed Tyndallization bacterial growth
- Clarified the reason that heat Outlined Koch’s
would sometimes fail to 1882
Ferdinand postulate
completely eliminate all
Cohn Microorganisms Development of
Paul Erlich
- “Sterile” was established Acid-fast stain

THE DEVELOPMENT OF ASEPTIC TECHNIQUES Hans Christian Gram stain developed
1884
Gram
observed that mothers who gave
Dr. Oliver
birth at home experienced fewer First Rabies
Wendell 1885 Louis Pasteur
infections than did mothers who Vaccination
Holmes gave birth in the hospital
Invention of the Petri
1887 Richard J. Petri
Dr. Ignaz - Father of Hand Hygiene Dish

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

Dmitri Iosifovich Discovery of Viruses recognized or named and placed in
1892 overall taxonomic scheme (genotypic
Ivanovski
and phenotypic characteristics)
T. Smith and F.I. Zoonosis - first
1893
Kilbourne described
CLASSIFICATION
Viral dependence on
Martinus living host cells for - Provided the initial evidence
1899
Beijerinck reproduction that some of the microbes in dust
recognized Carl von Linne and air have very high heat
(Linnaeus; resistance and that particularly
Proof the mosquitoes vigorous treatment is required to
1701-1778)
1900 Walter Reed carry the agent of destroy them
yellow fever - Developed Tyndallization
Discovered the cure
1910 Paul Erlich Carl von Linne’s Classification System
for syphilis
Alexander Discovery of Penicillin
1928
Fleming
J. Watson and F. Proposed and built
1953
Crick the DNA model
Development of the
W. Gilbert, F.
1977 DNA sequencing
Sanger
method
Invention of the
Kary Mulis Polymerase Chain
Reaction (PCR)

TAXONOMY
- Whittaker’s tree
- based on structural similarities
Greek taxes: arrangement; Greek nomos: law and differences, such as
- is the orderly classification and grouping of Robert
prokaryotic and eukaryotic
organisms into taxa (categories) Whittaker cellular organization, and the way
- it is based on similarities and differences in these organisms obtain their
genotype and phenotype nutrition.
GENOTYPE: genetic makeup of an WHITTAKER’S TREE
organism, or combinations of forms of
one or a few genes under scrutiny in an
organism's genome.
PHENOTYPE: readily observable physical
and functional features of an organism
expressed by its genotype.

THREE CATEGORIES OF TAXONOMY

1. NOMENCLATURE: is the assignment of
scientific names to the various taxonomic
categories and individual organisms
2. CLASSIFICATION: Attempts the orderly
arrangement of organisms into a
hierarchy of taxa (categories)
3. IDENTIFICATION: Is the process of
discovering and recording the traits or
organisms so that they may be

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

- devised a Three Domain System STANDARD RULES FOR DENOTING
of Classification
BACTERIAL NAMES
- there are two domains of
prokaryotes – based on cellular
Carl R. Woese organization and function Family name is capitalized and has an
(Archaea and Bacteria) and one "-aceae" ending (Micrococcaeceae)
domain (Eukarya or Eukarya), Genus name is capitalized and followed
which includes all eukaryotic by the species epithet, which begins with
organisms. a lowercase letter, both the genus and
THREE-DOMAIN SYSTEM OF CLASSIFICATION the species should be italicized in print
but underlined when written in script
(E.g. Staphylococcus aureus or
Staphylococcus aureus)
Abbreviated by using the first letter
(capitalized) of the genus followed by a
period and the species epithet (S.
aureus).
First two letters or the first syllable are
used when two or more genera names
begin with the same first letter (Staph.
And Strept. For Staphylococcus and
Streptococcus)
Escherichia coli (E. coli or Esch. coli) is a
bacterium, but Entamoeba coli (Ent. coli)
is an intestinal parasite
NOMENCLATURE
IDENTIFICATION
International Code of Nomenclature of
Bacteria (ICNB) or the Bacteriological GENOTYPIC CHARACTERISTICS: relate
Code (BC): provides the accepted labels to an organism’s genetic makeup,
by which organisms are universally including the nature of the organism’s
recognized genes and constituent nucleic acids
PHENOTYPIC CHARACTERISTICS: are
BINOMIAL SYSTEM OF based on features beyond the genetic
NOMENCLATURE level and include both readily observable
characteristics and characteristics that
- every organism is assigned a genus and a may require extensive analytical
species of Latin or Greek derivation Each procedures to be detected
organism has a scientific “label” consisting of SUBSPECIES: based on phenotypic
two parts: differences (abbreviated "subsp.")
Genus – the first letter is always SEROVARIETIES: based on serologic
capitalized differences (antigenic properties)
Species – first letter is always lower case (abbreviated "serovar")
○ PRINTED: Italicized BIOVARIETIES: based on biochemical or
○ SCRIPT/HANDWRITTEN: physiological test result differences
Underlined (separate line for (abbreviated "biovar")
genus and species) PHAGE TYPING: based on susceptibility
to specific bacterial phages
Analysis of ribosomal RNA (rRNA)

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

organelles
BY CELLULAR TYPE
Golgi bodies Present in some
PROKARYOTES: Gr. “before kernel” Present in some;
(nucleus) contain
Lysosomes
- domains Archaea and Bacteria hydrolytic
(Eubacteria) enzymes
- Simple cells that lacking
Present in all;
membrane bound nucleus Endoplasmic Absent in all lipid synthesis,
- Prokaryotes fall under the domain reticulum
transport
Archaea and Bacteria. Bacteria fall
Mitochondria Present in most
in either of these two domains
EUKARYOTES: Gr. eu: “well or good” and Nucleus Present in all
Gr. Karyon: kernel Present in algae
Chloroplasts for
- fungi, algae, protozoa, animals, photosynthesis and plants
and Plants o With membrane
Ribosome: site
bound nucleus
of protein
- Categorized under the domain synthesis Present in all Present in all
Eukarya (nonmembrano
us) size
CHARACT 70S consisting of In the inner
PROKARYOTE EUKARYOTE
ERISTICS Electron
50S and 30S membrane of
transport for
0.4-2 um in 10 - 100 um in energy subunits mitochondria
Typical size diameter 0.5-5 diameter >10 um and chloroplasts
um in length in length
Sterols in Absent except in
No nuclear Membrane cytoplasmic Mycoplasmatace Present
membrane, bound nucleus membrane ae
Nucleus
nucleoid region
Plasma Peptidoglycan in
of the cytosol
membrane most bacteria
In the nucleoid, In the nucleus
Location Peptidoglycan in Cellulose,
at the mesosome
most bacteria phenolic
Circular; Linear; Cell wall, if polymers, lignin
complexed with complexed with present (plant), chitin
Chromosomal
RNA basic histones (fungi), other
DNA
and other glycans (algae)
proteins
Present in most
Plasmids, small In mitochondria as an organized
Present; some
circular molecule and chloroplasts Glycocalyx capsule or
animal cells
of DNA unorganized
containing slime layer
accessory
Cilia Absent Present
information; most
Extrachromo
commonly found Flagella, if Complex cilia or
somal circular Simple flagella
DNA in gram-negative present flagella
bacteria; each
Pili and
carries genes for Present Absent
fimbriae
its own
replication; can
confer resistance
to antibiotics
Asexual (binary Sexual and
Reproduction
fission) asexual
Membrane
Absent All
-bound

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

BACTERIAL STRUCTURE AND FUNCTION

IMPORTANT CHARACTERISTICS OF
BACTERIA

PROKARYOTIC
Have no organelles; No membrane
enclosed structure
Do not have histones o Have 70S
ribosomes and are HAPLOID with a
single chromosome.
Cell wall: with peptidoglycan except for
Mycoplasma and Ureaplasma
ARCHAEA (ARCHAEOBACTERIA): more Cytoplasmic membrane: fluid
closely related to eukaryotic cells / found phospholipid bilayer with carbohydrate
in microorganisms that grow under and sterol
extreme environmental peptidoglycan - Site of energy production
conditions/lack Free Ribosomes: Site of protein synthesis
- Greek: (archaics) ancient, origin Unicellular; contains both DNA and RNA
from the earliest cells o Average size of 0.2-5.0 microns
- Those that belong in the domain - Smallest living organism:
Archaea are some of the most Mycoplasma
resistant - Largest: Bacillus
- organisms are found in extreme Multiplies by binary fission
environmental conditions. Biofilms: property of bacteria to attach on
- Has cell wall, plasma membrane, solid surface o Pathogenicity: ability of a
ribosomes and flagella (no microbe to produce disease in a
nucleus and membrane bound susceptible individual
organelles Virulence: relative ability of a
- Never contain peptidoglycan microorganism to cause disease or the
contain protein or glycoprotein degree of pathogenicity
wall structure known as S-layer - usually measured by the numbers
EXTREMOPHILES: lovers of the extreme of microorganisms necessary to
conditions cause infection in the host
E.g. Sulfurovum epsilonproteobacteria
HALOPHILES: salt-loving cells
- in Utah's Great Salt Lake Found in
environments high in salinity or
salt concentrations
E.g. Salinibacter ruber
THERMOPHILES: heat-loving cells
- In hot springs and deep ocean
vents
- Thrive in environments with
extreme heat
E.g. Methanobacterium wolfei

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

II. Based on Structure
VIRULENCE FACTORS
CELL ENVELOPE: Composed of layers
ADHERENCE FACTORS: pili/fimbriae (capsule, cell wall, cell membrane) that
ANTIPHAGOCYTIC FACTORS: capsule surround the bacterium.
and self-component of cell wall CELL WALL: also referred to as the
ENZYMES: Coagulase - S. aureus, peptidoglycan or murein layer
Fibrinolysin - spreading and clotting - Gives bacterial cell shape and
strength to withstand changes in
EXOTOXIN ENDOTOXIN the environmental osmotic
Released by all major Usually produced by gram pressures
gram (+) (-) organisms - Protects against mechanical
Exotoxin is excreted by It requires cell death for
disruption of the cell
living bacteria and it release (Cell wall - Some bacteria use the cell wall for
does not require cell disintegration) pathogenicity:
death for release; → M PROTEIN: major
metabolic product of virulence factor and
bacteria prevents phagocytosis for
Composition: mainly Composition: S. pyogenes
PROTEIN in nature Polysaccharide and lipids → MYCOLIC ACID:
responsible for acid
Effect: "Local" - one area Effect: “Systemic” all over
fastness of Mycobacterium
Not associated with fever the body
species and prevents
Toxicity: High Toxicity: Low digestion during
Stability to heating: Stability to heating: phagocytosis
UNSTABLE at 60 STABLE → POLY-D-GLUTAMIC ACID:
Bacillus species
Stimulates antitoxin Stimulates antitoxin
→ CHITIN: fungi
production: b (can be production: NO (cannot
converted into toxoid; be converted into toxoid; → L-FORM: organisms that
easily neutralized by anti- not easily neutralized by temporarily lost their cell
toxin) anti- toxin) wall as a result of
environmental conditions
Usually bind to specific Specific receptors not
→ Peptidoglycan consists of
receptors on cells found on cells
glycan chains of
Frequently controlled Synthesis directed by alternating
extrachromosomal (e.g. chromosomal genes N-acetyl-d-glucosamine
plasmids) by genes (NAG) and
N-acetyl-d-muramic acid
OTHER CHARACTERISTICS OF (NAM)
BACTERIA

I. Based on Classification
DOMAIN: Bacteria (Prokaryotes)
PHYLA: E.g. Proteobacteria, Firmicutes,
Actinobacteria, and Bacteroidetes
GENUS AND SPECIES: Based on genetic,
biochemical, and phenotypic
characteristics

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

GRAM + GRAM - - Motility is best seen at room
temperature
– Single-layered – Double Layered
– Thick protective – Thin peptidoglycan TYPES OF FLAGELLA
peptidoglycan layer (single−layer)
→ ATRICHOUS: absence of flagella
– layer (several layers) – Large periplasmic
– Small periplasmic space
→ MONOTRICHOUS: single flagellum in
layer – Presence of outer one end
– Absence of outer membrane → LOPHOTRICHOUS: multiple flagella in
membrane – No teichoic acid one end
– Has teichoic acid – Thickness: 10 → AMPITRICHOUS: single flagella in both
– Thickness: 15 80 nanometers ends
nanometers – Presence of porins → PERITRICHOUS: flagella around in the
– Absence of porins – High Lipid content: bacterium
– Very low lipid 15-20%
→ AMPHILOPHOTRICHOUS: multiple
content (2-5%) – Has
– No lipopolysaccharides
flagella in both ends
lipopolysaccharides Gram Staining Procedure: WAYS TO DEMONSTRATE MOTILITY
Gram Staining - No retention of
Procedure: crystal violet dye a. Flagellar stain
- Retains the - Appears pink in b. Hanging drop
crystal violet dye color. c. Semi-solid media
- Appears purple i. NON-MOTILE: growth is in the line
in color ii. MOTILE: outside the line
TYPES OF MOTILITY
CAPSULE: slimy area surrounding the
→ Tumbling, gliding, darting, cork screw,
cell wall, responsible for mucoid colonies
twitching, shooting star
- Usually made of polysaccharide or
polypeptide
- Neufeld-Quellung capsular Ag (+)
capsular swelling due to Ag- Ab
METACHROMATIC GRANULES: serves as
- Serotyping:
energy source and food reserves
→ Somatic O Ag - heat stable
- Composed of glycogen, lipids,
→ Vi Ag (Salmonella) and K
polyphosphates or
Ag (E. coli) - heat labile
pyrophosphates
PLASMA MEMBRANE: surrounds the
- stained using Albert, Lamb,
cytoplasm
Neisser, and Ljubinsky
- Site of energy synthesis (ATP site)
- Transport of nutrients and out of TYPES OF GRANULES
the cell → MUCH GRANULES: Mycobacterium
PILI/ FIMBRIAE: hair-like proteinaceous tuberculosis
structured made up of “pilin” → BABES-ERNST/METACHROMATIC
TWO CLASSES: GRANULES: C. dIptheriae
a. Common/ordinary pili → BIPOLAR BODIES: Yersinia pestis
b. Sex pili → SULFUR BODIES: Actinomyces
ENDOSPORES: composed of Calcium
dipicolinate/ Dipicolinic Acid
- Found in Clostridium and Bacillus RIBOSOMES: for protein synthesis
species - give the bacterial cytoplasm a
- highly resistant to desiccation, granular appearance when
heat and chemical agents viewed in the electron
FLAGELLA: whip-like structure used as microscope
an organ for locomotion MESOSOMES: point of attachment of
- Made up of “flagellin” chromosomes
- Antigenic (H-antigen)

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

- convoluted invaginations of cell Cocci in chains
membrane - important for DNA
Sarcinate Coccus in cubical packets
replication and cell division
CYTOSOL: fluid portion of the cell Cocci in clusters
- Contains ribosomes and various
types of nutritional storage Tetrads Packets of four
granules
NUCLEOID: where the bacterial DNA is
found; also known as nuclear body
- Contains bacterial chromosome

III. Based on Function
METABOLISM: enzymatic pathways for
energy production (aerobic or anaerobic)
REPRODUCTION: binary fission for
asexual reproduction
GENETIC EXCHANGE: conjugation,
transformation, transduction for genetic
variation
SURVIVAL: endospore formation in some
bacteria under harsh conditions B. Bacilli (Bacillus)
- Rod-shaped, cylindrical or elongated
IV. Based on Morphology
Single bacilli Two cocci adjacent to each other
Diplobacillus Coccus in cubical packets
Streptobacilli Bacillus in chain
Bacillus that are small, short,
Cocobacilli
stout/plump
Irregular bacilli

C. Spirilla (Spirals)
- Helical or twisted bacteria
- Spiral with two or more curves, quite rigid
- Loosely twisted spiral resembling a stretched
A. Cocci (Coccus)
spiral
- Round, spherical-shaped bacteria - Tightly twisted spiral resembling a cork
- May occur singly, in pairs, in chains or in screw
clusters - Tightly twisted spiral with one or both ends
Diplococcus Two cocci adjacent to each other bent into a hook, sometimes even
resembling an interrogative symbol

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

V. Antigenic Determination Based on BACTERIAL GENETICS
Serological Typing

O Antigen: Associated with the cell wall DNA
H Antigen: Associated with the flagella
K Antigen: Associated with the capsule - Deoxyribonucleic acid
Vi Antigen: Specific capsular antigen of - It is a double-helical chain of
Salmonella typhi deoxynucleotides.
- The helix is a double strand twisted
VI. Based on Molecular Techniques together, which many scientists refer to
as a spiral
PCR: Amplification of specific DNA
sequences THE DISCOVERY OF DNA
DNA Sequencing: determines the
genetic sequence
FRIEDRICK Discovered DNA in 1869
RFLP: restriction fragment length MIESCHER
polymorphism for DNA profiling
FISH: Fluorescent in situ hybridization for PHOEBUS A. T. Discovered the composition of
LEVINE DNA in 1920s
detecting specific DNA/RNA sequences
in cells ROSALIND Discovered the helical structure
FRANKLIN by x-ray crystallography
JAMES Described the three-dimensional
WATSON and (3D) structure of the DNA
FRANCIS CRICK molecule in 1950s

NUCLEOTIDE COMPOSITION

Phosphate group (PO4)
Cyclic five-carbon pentose
Nitrogen-containing base
NITROGENOUS BASES IN NUCLEOTIDES
- PURINE: consists of a fused ring of nine
carbon atoms and nitrogen

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 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

- PYRIMIDINE: consists of a single ring of CONJUGATION: horizontal transfer of
six atoms of carbon and nitrogen genetic material by cell-to-cell contact
TRANSPOSON: some fragments of DNA
are mobile and can jump from one place
in the chromosome to another place
- All deoxynucleotides made up of MUTATION: changes that occur in the
combinations of four chemical units DNA code and often result in a change in
called nucleotides: the coded protein or in the prevention of
Adenine (A) its synthesis
Thymine (T) GENETIC RECOMBINATION: a method
Cytosine (C) by which genes are transferred or
Guanine (G) exchanged between homologous
(similar) regions on two DNA molecules,
forming new combinations of genes on a
→ Adenine - Thymine (A with T) chromosome
→ Guanine - Cytosine (G with C)
MECHANISM OF GENE TRANSFER

TERMINOLOGIES TRANSFORMATION: the uptake and
incorporation of free or naked DNA into a
bacterial cell
GENOTYPE: the genetic potential of the
DNA of an organism
PHENOTYPE: consists of observed
characteristics by the genome
REPLICATION: The duplication of
chromosomal DNA for insertion into a
daughter cell
BINARY FISSION: a single bacterial cell
divides into two genetically identical
daughter cells TRANSDUCTION: the transfer of bacterial
TRANSCRIPTION: the synthesis of genes by a bacteriophage from one cell
mRNAa by the enzyme RNA polymerase to another
using one strand of DNA as template
TRANSLATION: the synthesis of a specific
protein from the mRNA code
PROTEIN EXPRESSION: synthesis of
protein
CODON: group of three nucleotides in an
mRNA molecule that signifies a specific
amino acid
ANTICODON: the triplet of bases on the
tRNA that bind the triplet of bases
(codon) on the mRNA BACTERIOPHAGE: consists of genetic
material (DNA or RNA) surrounded by a
GENETIC ELEMENTS AND protein coat
ALTERATIONS CONJUGATION: the transfer of genetic
material from a donor bacterial strain to a
BACTERIAL GENOME: consists of a recipient strain
single, closed, circular piece of dsDNA
that is super coiled to fit inside the cell
PLASMIDS: small, circular pieces of
extrachromosomal dsDNA

PAGE 12 Viray, M.S.Y. - 3B ˚ ༘♡ ⋆｡˚ ❀
 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

BACTERIAL GROWTH AND NUTRITION

BACTERIAL GROWTH

- Refers to the increase in the number of
bacteria
- This growth is affected by various factors
such as optimum growth requirements,
dynamics of growth, including the use of
a medium that can be artificially
prepared in the laboratory
RESTRICTION ENZYME: produced that
cut (restrict) incoming, foreign DNA at NUTRITIONAL REQUIREMENTS
specific DNA sequences
- Autotroph
CARBON
- heterotroph
ENERGY - Phototrophic
SOURCE - chemotrophic
WATER/ MOISTURE/ HUMIDITY
MINERAL Needed as co-factors in various
ELEMENTS metabolic process of the bacteria
- Lithotroph, organotroph
ELECTRON
- NADH reduced from NAD
SOURCE
- FADH2 reduced from FAD
- Needed for the synthesis
of proteins
- Free nitrogen from the air
NITROGEN - Nitrogenous compounds
in the culture media (e.g.
peptone, yeast, beef
extract)
- Halophilic bacteria/
halophiles
SALT - Organotroph
- NADH reduced from NAD
- FADH2 reduced from FAD

ADDITIONAL/SPECIAL GROWTH
REQUIREMENTS

FASTIDIOUS:
Haemophilus spp.
- Requires both X & V factor
- Culture Media: Blood Agar Plate
- 1st priority: 5% defibrinated sheep’s blood
- 2nd priority: horse blood
- 3rd priority: rabbit’s blood
- Least priority: human blood
X Factor (Hemin/ Hematin)
V Factor

PAGE 13 Viray, M.S.Y. - 3B ˚ ༘♡ ⋆｡˚ ❀
 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

ENVIRONMENTAL REQUIREMENTS BACTERIAL METABOLISM

TEMPERATURE - biochemical reactions bacteria use to
break down organic compounds and the
Incubation temperature for most
reactions they use to synthesize new
bacteria and viruses: 35° - 37°C
bacterial molecules from the resulting
Incubation temperature and time for
carbon skeletons
AEROBES: 35° - 37°C for 18-24 hours
- Carbohydrates 🡪 Glucose 🡪 Pyruvic acid 🡪
Incubation temperature and time for
energy + By-products
ANAEROBES: 35° - 37°C for 2-48 hours
Diagnostic Laboratory usually incubate
cultures for bacterial growth at 35°C FERMENTATION
Pseudomonas and Campylobacter can
grow at 35°C and 42°C - anaerobic process carried out by
Mesophilic obligate, facultative and aerotolerant
Psychrophilic/ Cryophilic anaerobes
Thermophilic - Also important because it generates
Hyperthermophilic/ Extremely nicotinamide adenine dinucleotide (NAD
Thermophilic - molecule necessary for maintaining the
Eurithermophilic Krebs cycle)
Sternothermophilic - mixture of end products (e.g. lactate,
butyrate, ethanol, and acetoin)
pH accumulates in the medium
Acidophilic - used loosely in the diagnostic
Alkaliphilic microbiology laboratory to indicate any
Osmophilic type of utilization—fermentative or
oxidative—of a
carbohydrate—sugar—with the resulting
BACTERIAL GROWTH PHASE production of an acid pH
GENERATION TIME
Time to replicate AEROBIC RESPIRATION (OXIDATION)
Refers to the stages of bacterial growth
Fast Growing Bacteria: 20 minutes - an efficient energy-generating process
Slow Growing Bacteria: 24 hours molecular oxygen (O2) is the final
electron acceptor
- Obligate aerobes and facultative
anaerobes undergo aerobic respiration
- Certain anaerobes can carry out
anaerobic respiration, in which molecules
other than molecular oxygen, such as
nitrate and sulfate, act as the final
electron acceptors.
- Anaerobic respiration is less energy
yielding than aerobic respiration

THREE MAJOR METABOLIC PATHWAYS

- Pyruvate: can be further catabolized
either fermentatively or oxidatively.
1. Embden-Meyerhof-Parnas (EMP)
glycolytic pathway
2. Pentose phosphate pathway

PAGE 14 Viray, M.S.Y. - 3B ˚ ༘♡ ⋆｡˚ ❀
 CLINICAL BACTERIOLOGY
LECTURE - MICRO 1 Ms. Giane Paola T. Tanjuaquio, RMT *:･ﾟ✧*:･ﾟ

3. Entner-Doudoroff pathway glucose must not be present if the ability
to ferment another sugar is being tested
GLUCOSE 🡪 PYRUVIC ACID/PYRUVATE – ability to ferment lactose is an important
step in classifying members of the family
Embden-Meyerhof-Parnas Glycolytic
Enterobacteriaceae
Pathway
○ classified as either lactose
– Major source (90% glycolysis)
fermenters or lactose
– Yields 2 ATOs (Anaerobic)
non-fermenters
Pentose-Phosphate (Phosphogluconate)
○ utilization of lactose by a
Pathway
bacterium requires two steps:
– 10% glycolysis
1. requires an enzyme, β-galactoside permease,
– Yields 38 molecules of ATPs
for the transport of lactose across the cell wall
(Anaerobic)
into the bacterial cytoplasm
2. occurs inside the cell and requires the enzyme
PYRUVATE 🡪 ENERGY + β-galactosidase to break the galactoside bond,
BY-PRODUCTS releasing glucose, which then can be fermented.
Respiration (Aerobic Process)
– Kreb’s Cycle
– Electron Transport Chain
– Glucose 🡪 CO2 and H2O
Oxidation
– Glucose - Acid
Fermentation
– Anaerobic process carried out by
both obligate and facultative
anaerobes
– Organic molecule is the final
electron transporter

CLASSIFICATION OF FERMENTATION
BASED ON END PRODUCTS
Alcoholic Fermentation
Homolactic Fermentation
Heterolactic Fermentation
Propionic acid Fermentation
Mixed acid Fermentation
Butylene Glycol Pathway
Butyric Acid Fermentation

CARBOHYDRATE UTILIZATION AND
LACTOSE FERMENTATION
– ability of microorganisms to use various
sugars (carbohydrates) for growth is an
integral part of many diagnostic
identification
– fermentation of the sugar is usually
detected by acid production and a
concomitant change of color resulting
from a pH indicator present in the
culture medium
– Bacteria generally ferment glucose
preferentially over other sugars, so

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