BACTERIOLOGY.pdf

Transcript

BACTERIOLOGY Early discoveries:
LESSON 1: HISTORY OF MICROBIOLOGY 1. Robert hooke
Personalities contributing in development of o Observed tissue plants, he used simple
microbiology magnifying glass
o Suggested all living things a re made up
1. LUCRETIUS (roman philosopher) & GIROLAMO from cell.
FRACASTRO (physician) o Cell= little boxes
o Believed invisible creatures were 2. Anton Van leeuwenhoek
responsible for disease; any small insects o Not a scientist he is a haber dasher that
2. FRANCESCO STELLUTI uses lenses to examine cloth
o Observed bees and weevils using a o “Animalcules”
microscope in early 1600s o first to observe bacteria and protozoa
During ancient civilization, they believe in THEORY OF 3. Louis Pasteur
o French chemist
SPONTANEOUS GENERATION
o Father of microbiologist
“Life arise from non-life” o Theory of Biogenesis “Life comes from life”
o Microbes can be destroyed by heat
People who supported the theory:
o Experiment: One neck flask
1. Aristotle: readily observable that aphids arise o Hypothesized “germ theory of disease”
from the dew which falls on plants, fleas from  Microorganisms are
putrid matter, mice and … responsible for infectious
2. John Needham: disease
o Microbes reappear because of spont. Gen.
o Experiment: He boiled chicken broth, the
next day the broth has microbes (bcoz
walang takip)
o Hypothesis: life re-emerged due to
spontaneous generation
o British clergy man
 Spallanzani challenged needham’s theory
o Microbes appear from needhams
experiment came from air
o Experiment: boil the broth but he sealed it;
no microbes appear

People who do not support the theory:
GERM THEORY OF DISEASE
1. Francesco Redi
o Experiment: He put meat on 3 diff. jars with 1. Oliver Wendel Holmes
cover o Reiterate the importance of handwashing
o Flask 1 (open)- maggots appear 2. Ignaz Semmelweis
o Flask 2 (with gauze)- maggots o Noticed death rated higher in maternity
appear on the net; maggots laying wards
eggs on the top of the net 3. John Snow
o Flask 3 (sealed)- no maggots o Good public hygiene
o First to formally challenge S.G o One of the father of epidemiology
o “maggots unable to grow on meat if meat o Traced the source of cholera outbreak in
was covered with gauze” London
o Believed that maggots were because of flies o Calculate the dosage of anethesia
o “sicknes is caused by a bad care”
4. John Tyndall o Cowpox and Smallpox: pag nagkaroon ng
o Bacteria existed in 2 forms: cowpox yung tao di na nagkakaroon ng
a. Heat Stable form (endospore) smallpox due to immunity
b. Heat Sensitive form (vegetative 8. Paul Ehrich
form) o Dermatologist
o need intermittent and prolonged heating to o Wanted to find out the magic bullet to cure
destroy spores syphilis
o Tyndallization: process of sterilizing liquid o Developed Sarlvarsan preparation 606 “
by heating salvation from syphilis”
5. Robert Koch o The agent that causes syphilis can be
o Confirmed germ theory of disease eliminated throough arsening derivatives
o Originate use of two o Chemotherapy approach
o Developed pure culture techniques 9. Walter reese
o Culture way he used o Suggested to Koch to used agar
1. Gelatin: nakakain ng bacteria, nalulusaw 10. Richard Petris
2. Agar (extract from seaweed): bacteria o Petri dish
will stay; not being metabolized by 11. Christopher Gram
bacteria o Staining method
o He was able to see the causative agent of 12. Sabouraud
tuberculosis; mycobacterium tuberculosis o Yeast and molds
(Koch’s Bacillus) 13. Ivanoski
o Koch’s postulate o Tobacco mosaic
14. Waksman
o Tetracydine & streptomycin

Discovery of antimicrobial
1. Dogmak
o prontosil
2. Fleming
o Discovered penicillin by accident
3. Salk and Savin
o Polio virus vaccine

o Problem:
o Pwedeng asymptomatic yung  Ruska
patient pero may bacteria parine o Electron microscope, 1938
o May bacteria tayo sa loob ng  Watson & crick
katawan na healthy o DNA, 1953
6. Jospeh lister:  Jacob & Monod
o Father of modern antisepsis o Protein synthesis, 1965
o Surgeon that applied germ theory to
surgery
o Used of carbolic acid
o He believed louis Pasteur
o Infection is best avoided by preventing
bacteria from getting in the wound
7. Edward Jenner
o Created first vaccine
 LESSON 2: MORPHOLOGY  single celled
 through budding
Micro- small
o Mold
Bio- life  Multicellular
 Reproduce by using pores
Logus- study - Illness: Athletes foot, ringworm
Microbiology- study of living microorganism including  Multicellular parasites
viruses o Live in or on another organism and use
it for nourishment
- Broad discipline that includes pure sciences
PARASITIC WORMS
Pure:
1. Round
1. Bacteriology 2. Flat
2. Mycology 3. Tape
3. Immunology 4. Insects
4. Virology 5. Mosquitoes
5. Parasitology

Applied: 4. BACTERIA
- Single celled prokaryotic organism
1. Chemotheraphy - Reproduce by binary fission
2. Agricultural - Shape
3. Paleomicrobiology: study of ancient microbes o Cocci- round
4. Biotechnology o Bacilli- elongated
o Spiral
Bioremediation- used microbes to remove toxins
- Ability to retain dyes
Microbial World o Gram (+): violet (crystal violet)
o Gram (-): red (safranin)
1. VIRUS
- Ability to grow with or w/o air; aerobic or
- Smallest known infectious agents
anaerobic
- Subcellular microorganisms
- Not a cell; contain only nucleic acid and protein
coat
Classification of Microorganisms
- Nucleic acid can be either DNA or RNA but
never both  Taxonomy: science of organizing, classifying &
- Must live inside the cell in order to grow naming living things
- Illness: common cold, flu, heap, warts, AIDs, o Originated by CARL VON LUNNE
measles o Placed into a classification system
2. PROTOZOANS  Arrangement of bacteria into
- Singled celled eukaryotic organism larger than groups
bacteria  By serotypes, antimicrobial
- Found in soil and water resistance
- Illness: malaria (caused by plasmodium), o Nomenclature is process of giving
amoebic dysentery, trichomoniasis vaginitis naming ,following binomial: by 2
- The only infective intestinal parasite is names, genus and species.
Histolytica o Identification- use practical schemes to
- Could be amebae, flagellates, ciliates, and distinguish 1 from another; may criteria
parasitic sporozoans. 1. DOMAIN
3. FUNGI a) Eubacteria
- Eukaryotic with rigid cell wall Prokaryotic
o Yeast
 Most disease causing Cell wall is chemically Cell wall is simple
True bacteria complex
With peptidoglycan in cells DNA is single circular DNA is linear multiple
b) Archaea chromosome copies
“extremophiles”
Odd bacteria that live in extremes Both have ribosomes
environments
Not associated with disease MORPHOLOGY OF BACTERIA
Can be found under the ocean, volcanoes
etc.  Size:.2 - 1 micrometer
c) Eukarya Cocci
Have nucleus and organelles (humans, Bacilli
animal, plants)  Rod shape
2 domain is dedicated for bacteria and another living  Coccobasicllus: enither sphere or
organisms are in Eukarya. elongated
2. KINGDOM Spiral
a) prokaryotes  Can cause lepto
3. PHYLUM  Vibrio- comma; causes cholera
a) Gracilicytes  Spirillum- rigid body; nasa labas flagella
4. CLASS  Spirochete- yung flagella nakaikot sakanya
a) scotobacteria kaya flexible
5. ORDER
a) eubacteria
6. FAMILY
a) enterobacteriaceae
7. GENUS
8. SPECIES

 Mnemonics: Dumb Kings Play Chess On Funny
Green Squares

Naming organism
- italicized or underlined
- Ex: Staphylococcus aureus (S. aureus); Staphylococcus
aureus
 Genus: Noun, always capitalized
 Species: adjective, lowercase

All cocci are gram positive except Veillonella,
Megaspoera, Neisseria, moraxella, Branhamella Bacterial cell:
- contains 70 ribosomes
All bacilli are gram negative except  Glycocalyx
Contains sticky protective coating
Prokaryotes Eukaryotes Capsule: fixed
Small;.2-1 micrometer Slime: loosely attached
Big, 10-100 micrometer
 Cell wall
Nucleus is absent because Nucleus is present Gives shape; contains peptidoglycan for
there is no nuclear mem. staining properties
 Cell membrane  Capsule: glycocalyx that is firmly attached, sugar-
Allow in and out substances coat; polysaccharide
 Plasmids It evades phagocytosis
Extra chromosal DNA  Flagella
 Pili  Pili
Hairlike projections  Endospore
 Fimbriae- common pili, use for  Survival mechanism
attachment  Bacillus and Clostridium
 Sex Pili- for conjugation; when a acteria  Can regenerate
wants to donate its copy of plasmids to  Plasmid
another bacteria May antibiotic resistance genes
 Flagella  May gene na pwede mag produce ng
Propels bacteria antibiotics na kaya mag resist
Cocci do not have this
 Lopotricus: isang end lang may flagella
 Amphitricus: magkabilang dulo merong
flagella
 Peritricus: buong katawan meron
 Atricus: walang flagella

Mycoplasma: bacteria na walang cell wall

LESSON 2: MICROBIAL GROWTH REQUIREMENTS

Requirements for growth

1. Physical
a) Temp
b) Ph
ESSENTIAL STRUCTURES OF BACTERIA c) Osmotic Pressure
 Cell wall 2. Chemical
peptidoglycan a) Carbon
Gram positive: inner cell membrane and outer b) Nitrogen, sulfur, phosphorus
cell wall (2 layers) c) Trace elements
Gram negative: inner cell membrane, outer d) Oxygen
cell wall, outermost outer membrane (3 layers) e) Organic growth factors
 Cell membrane
Bilayer of phospholipids
 Cytoplasm
Location of nuclear materials
 Nuclear Material
Circular shape, almost like a flower

NON-ESSENTIAL STRUCTURES OF BACTERIA
PHYSICAL GROWTH Bacteria can be classified into Halophiles:

A. TEMPERATURE: bacteria only grown within a - VIBRIO: example of halophilic bacteria;
limited range of temperature nakukuha pag kumakain ng seafood

Psychrophiles Psychro = cold Psychotrophs Extreme Halophiles - Can withstand
- Cold  0-15 deg (obligate) 30% salt
loving concentration
Moderate -
Types: psychorphiles
Facultative halophiles - 2-5% salt
 Psychotrophs  20-30 deg concentration
 Moderate
psychorphiles
CHEMICAL GROWTH

A. CARBON
Mesophiles - affects Min: 25 deg - Structural backbone of living matter
human - All organic compounds are made of carbon
Max: 40 deg
o Phototrophs: depends on light;
Optimum: 35- archaeans
47 deg o Chemotrophs: depends on chemicals

Thermophiles - love Min: 50 Chemoheterotrophs - If the carbon
higher source is organic
Max: 60 compound
temp

Hyperthermophiles - usually 80-121 deg; Chemoautotrophs - If the carbon
archaeans pwede ma- source is carbon
- love to be autoclave if dioxide
in very walang
Photoheterotrophs Light; If the carbon source
hot temp pressure
is organic compound

Photoautotrophs Light; If the carbon source
B. pH is carbon dioxide
- Lowest recorder ph that can be associated woth
bacteria is ph 1 (chemoautotrophic)
- Bacteria can grow narrow ph range near B. NITROGEN, SULFUR, PHOSPHORUS
neutrality between 6.5-7.5 ; most are - For protein and nucleic acid synthesis
meosphiles - Nitrogen: 14% dry weight of bacteria
- Very few bacteria grow below ph 4 - Sulfur: 4% dry weight of bacteria
- Molds & yeast: 5 & 6 pH - K, Mg, Ca: co factors for enzymes being
produced by bacteria
C. OSMOTIC PRESSURE
- Water for growth C. TRACE ELEMENTS
 HYPERTONIC - Fe, Cu, Me, Zn
o Madaming salts - Present in tap water
o Mag-sshrink
 HYPOTONIC
o It will swell and then burst
 D. OXYGEN
- We can consider oxygen as a poison; they in
their system that can neutralize the poisonous
effect of oxygen
- Singlet oxygen: can inactive catalase
- Peroxidase and catalase: neutralizing enzyme
for oxygen
- Peroxidase: can convert to water but no oxygen
- Anaerobes walang SOD
E. ORGANIC GROWTH FACTOR
Obligate aerobes - Strict - Amino acids
- They need - Purines
oxygen - Pyramidines
Facultative Anaerobes - Part-time aerobe
and anaerobes
- Basically they are Generation time: required for a cell to divide most
aerobes bacteria doubling time is 1-3 hrs, others 24 hrs or more.
- Their energy can PHASES OF BACTERIAL GROWTH
decrease in
absence of A. LAG PHASE
oxygen - Preparing to synthesize
B. LOG PHASE/ EXPONENTIAL GROWTH
Obligate Anaerobe - Strictly no - Period of growth; most sensitive; regenerate
oxygen - When they are more active
Aerotolerant anaerobe - Can tolerate C. STATIONARY PHASE/ EQUILIBRIUM
oxygen - Microbial deaths
- Basically they are - Deaths are balance with new bacteria arising
D. DEATH PHASE/ LOG DECLINE
anaerobes
- Number of deaths exceed number of new
Microaerophiles - Can tolerate little bacterial cells
amount of
oxygen DETERMINATION OF GROWTH
- Can only tolerate (direct)
5-10% of oxygen
- Onti lang ang 9. PLATE COUNTS
Peroxidase and - Measures of viable cells
catalase - Colonies should be 30-300 to be countable
o POUR PLATE: mix yung agar at inoculate
Capnophiles - Love carbon o SPREAD PLATE: solid na yung media tas
dioxide ippour na lang yung inoculate
- Ex: Lieseria
 - Higher acid production higher bacteria
15. DRY WEIGHT
10. FILTRATION
- For molds and fungus
- At least 100 ml of water are passed through a
- Filtered to remove extraneous materials and
thin membrane filter whose pores are too small
dried in a desiccator
to allow bacteria to pass

CELL METABOLISM

- Sum of all chemical reactions
- Energy balancing act

MICROBIAL METABOLISM: transformation of energy;
from eating

ATP
- Kind of fuel needs to run a cell
- Energy storing nucleotide
- Consists of adenine, ribose & 3 phosphate
11. MPN METHOD
- For water bacteriology OXIDATION-REDUCTION REACTION
- Statistical estimation technique since the REDOX: chemical reaction in which electrons are gained,
greater the no. of bacteria in a sample, the lost or shared in chemical reaction; addition of electrons
more dilution is needed to reduce intensity
12. DIRECT MICROSCOPIC COUNT OXIDATION: removal of electrons
- For milk Sa pagmemetabolize klailangan ng electron carriers:
- Placed within defined area on microscopic slide FADH and NADH

WHAT IS NADH?

- Special molecules that cells use to carry
electrons

METABOLIC REACTIONS

1. Anabolic: synthesize
2. Catabolic: breakdown
 EXERGONIC: produce more energy than they
can consume
Breed count  ENDERGONIC: consume more energy than they
Petroff-hauser count can produce

Electronic cell counters Pag sobrang catabolic reactions= madaming waste

Pag sobrang anabolic process= kulang ng supply or
production
(indirect)
CARBOHYDRATE CATABOLISM
13. TURBIDITY
- Use of spectrophotometer  Aerobic cellular Respiration
- Higher turbidity, the greater number of bacteria o Results in complex breakdown of
14. METABOLIC ACTIVITY glucose
- Higher no. of waster products, higher bacterial  Anaerobic respiration and fermentation
growth o Partially breakdown glucose
Cellular respiration: energy generating process - Para maraming ATP maproduce
- Proton gradient: to pump protons from one side
Aerobic Sub Pathways
to the other; difference in potential energy; ATP
A. Glycolysis to ADP
B. Synthesis of pyruvate to acetyl coA - Oxygen ang product
C. Krebs cycle
D. ETC

A. GLYCOLYSIS ANAEROBIC CELL RESPIRATION
- Energy investing stage: nag iinvest ng ATP to
breakdown 6 carbon
- Energy conserving stage
- Net ATP: 2
- Final Product: 2 molecules of pyruvic acid and
NADH
- Occurs in CYTOPLASM

Alternative:

1. Pentose Phosphate Pathway
- 5 carbon sugar
- Net gain of 1 mol of ATP plus 12 NADH
2. ENTER DOUDOROFF - Final product are nitrate, sulfate, carbon dioxide
- Podruce 2 mols of NADH & 1 mol of ATp - Not all electron transport chain is used so less
- Pseudomonas, trisodium gumagamit and atp na naprodruce, 2 lang
- Lactic acid fermentation and alcoholic
fermentation
B. Synthesis of Acetyl CoA GLYCOLYSIS: pwede sa anaerobic and aerobic
C. Krebs Cycle
- Occurs in CYTOPLASM in prokaryotes;
MITOCHONDRIA if eukaryotes CELL GENETICS
- 6 NADH 2 FADH
- 3 NADH, 1 FADH, 1GD, 2 Carbon - Single circular chromosomes that are filled with
genes (important genes)
- Not enclosed in a nuclear membrane
D. ETC - Haploid
- In CELL MEMBRANE; CRISTAE OF
MITOCHONDRIA if eukaryotes
GENOME SIZE LYTIC PHAGE (virulent) - Iinject niya yung
nucleic acid
- 0.16 Mb between 10 Mb
- Iinfect nung
- Base pairs: adenine , guanine, cytosine, tyrosine
virus yung
- Nagkakasya dahil sa super coiling
bacteria;
Ibbreakdown
ang bacterial
PLASMID cells
- Contains not so important tools - kukunin niya
- Extrachromosomal DNA yung materials
- They encode genes, producing of antibiotics na gusto niya
(prostoson) parta makabuo
ng kagaya niya
Bacterial reproduction is through binary fission; - Mas maraming
vertical gene transfer genes
makukuha

A. CONJUGATION TEMPERATE OF PHAGE - It will just
- cell to cell transfer through sex pilus recombine
(lysogenic)
- huling tinatransfer ang sex pilus nucleic acid to
the breakdown
of bacterial cell
to produce more
phages
- Didikit lang sa
chromosome ng
cell
- Can also become
virulent if
stressed
- Lalabas siya sa
pagkakadikit sa
bacteria and
B. TRANSFORMATION makukuha yung
- Take up freely floating DNA portion of
- Dapat competent cells para maka take up ng bacterial DNA
DNA - Konti lang
- Ginugutom ang bacteria to become competent makukuha
- Gram positive ang mas competent
- Must be integrated to the recipient cells
through recombination

 GENERALIZE TRANSDUCTION: random
C. TRANDSUCTION gene, bacteriophage chop us the host
- Use of phages- nag iinfects ng bacteria chromosomes into small fragments
- Natransfer yung dna from one bact to another
  SPECIALIZED TRANSDUCTION: specific sites like appendix
gene; konti lang ang pwede niyang and tonsil, general
matransfer effects are produced.
 Only in a certain area
of the body

Cross infection  When a patient
suffering from a
disease and new
infection it set up
from another host or
external source
LESSON 3: INFECTION AND IMMUNITY

Infection: injurious contamination of body either by Nosocomial infection  Hospital acquire
bacteria, viruses, fungi etc. infections

 Localized: confined to one part of the body Subclinical infection  It is one where clinical
effect are not
 Generalized (systemic): spread throughout the
apparent
body
 The infection is in the
patients but there are
Classification of infection
no signs and
Primary infection  Initial infection with symptoms that would
organism in host tell you that the
 First time that the patient is infected
host will encounter a with the certain
microbe, virus, or any microbe
microbe is the
primary infection
ACUTE, SUBACUTE AND CHRONIC
Reinfection  Subsequent infection
 ACUTE
by same organism in a
o rapid onset usually by a relatively
host (after recovery)
rapid recovery
 After recovery, the
o Examples: Measles, mumps,
same organism will
influenza
attack the host
o These are acute diseases you would
Superinfection  Infection by same recover from 1 to 2 weeks
organism in a host  CHRONIC
before recovery o Has a slow onset and last a long
time.
Secondary infection  When in a host whose
o Examples: Tuberculosis, leprosy,
resistance is lowered
syphilis
by preexisting o It will take a long time for a patient
infectious disease, a
to recover from these set of illness
new organism may
 SUBACUTE
set up infection (diff
o Diseases that come on more
agent)
suddenly than chronic diseases but
Focal infection  It is the condition less suddenly than acute diseases.
where due to o Somewhere in between acute and
infection at localized chronic illness
 o Example: Bacterial endocarditis diseases are mostly
easily transmitted
during this stage
LATENT INFECTIONS  Specific signs and
symptoms are
 disease that may go from being symptomatic to
present that identify
asymptomatic and then back to being having illness
symptomatic
 remains inactive for a period of time and then Convalescent Period  time when the person
becomes active again when it changes its mind recovers. Person may
and produce symptoms again recover from the
 Ex: syphilis illness but there may
be permanent
damage of tissues of
4 PERIODS IN THE COURSE OF AN INFECTIOUS DISEASE the affected area

Incubation Period  that elapses between
the arrival of the
EPIDEMIOLOGIC TRIAD
pathogen and the
onset of symptoms
 incubation period will
depend on the nature
of the microbe that
arrived in the
body/system. (short
or long)

Prodromal Period  time during which the
patient starts to feel
something is wrong
but do not experience
yet the actual
symptoms of the
disease
 Signs and symptoms
are present but not
specific (nonspecific
signs and symptoms)
 Ex. Fever, feeling
heavy
 The period wherein
you know something
is wrong in your body
but don’t know the
cause.

Period of Illness  The time when the
person experiences
the symptoms of the
disease.
Communicable
 WHY INFECTION DOES NOT ALWAYS OCCUR  Part of cell wall of gram
negative
1. Microbe land at an anatomical site where it is
 Can cause shock, fever
unable to multiply
2. Pathogen must attach to specific receptor Characteristics:
3. Antibacterial factors that destroy growth of
- Proteins polysaccharide lipid complex heat
microbes
stable
4. Overall health status
- Forms part of cell wall (don’t diffuse into
5. Person maybe immune
medium)
6. Phagocytic WBC may destroy it before having an
- Obtained only by cell lysis
opportunity
- They have no enzymatic action
- Effect is non-specific action
- Indigenous Microbiota: they live inside us that
- No specific tissue affinity
can both cause harm and prevent; Nagiging
- Active only in large doses 5 to 25 mg
virulent and bacteria if napunta sa ibang site
- Weakly antigenic
CHARACTERISTICS OF PATHOGEN - Neutralization by antibody infective
- Cannot be toxoided
1. Able to enter the body
- Produce in gram negative bacteria
2. Able to multiply
3. Cause damage
o EXOTOXINS:
4. Capable to resist the hist defense
 Excreted out
 Produce mostly by gram
positive
 PATHOGENECITY: ability of microbial species to
produce disease Characteristics:

- Heat labile protein
VIRULENCE
- Diffuse readily into the surrounding medium
- ability of microbial strains to produce disease
- Highly potent, e.g. 3kg botulinum can kill all the
- how fatal would be the disease
inhabitants of the world
- They are generally formed by Gr+ bacteria and
VIRULENCE FACTORS
also by some Gr- organisms like Shigella, V.
(pathogenic ang bacteria if meron siya nito)
cholerae, and E. coli
A. ADHESION
- Usually produced primarily by gram positive
- Attachment of bacteria to body surfaces
- Exotoxin is specifically neutralized antitoxin
- ADHESINS AND LIGANS:
- Can be separated from culture by filtration
o describe the molecule on the surface of
- Action is enzymatic and it has specific tissue
the pathogen that is able to recognize
affinity
and bind to a particular receptor
- Cannot cause pyrexia (high fever) in a host
o binds to specific surface of cells
- Can be toxoided
o ADHESINS: sa bacteria
o LIGANS: sa host EXOTOXINS TYPES
B. INVASIVENESS
- Ability to spread in a host tissue after Neurotoxin  most potent exotoxin
produced by
establishing infection
Clostridium tetani
- Invasive=generalized; if hindi invasive=localized
(causative agent of
C. TOXIGENICITY
tetanus) and
- Bacteria produce 2 types of toxins
Clostridium
o ENDOTOXINS
 Inside botulinum
 Tetanospasmin
 o spastic protein synthesis
paralysis killing mucosal
 Botulinum epithelial cells and
o flaccid PMN’s
paralysis (polymorphonucleus)
 affects brain  avirulent

Enterotoxins  produced in the
intestine
VIRULENCE FACTORS (exoenzyme)
 Toxin B produced by
C. difficile damages 1. communicability- survival and distribution of
the surface of the organism in a community; kung na-ttransfer siya sa
colon leading to ibang tao
pseudomembranous 2. coagulase- prevent phagocytosis by forming fibrin;
colitis s. aureus.
 Cause diarrhea and 3. fibrinolysin- promote of spread of infection; breaks
sometimes vomiting down fibrin barriers in tissue
4. hyaluronidase- breaking down hyaluronic acid;
Toxic shock syndrome  Produced by strains
spreading factor.
toxin (TSST) of S. aureus and S.
 Hyaluronic acid: cement that hold tissues
pyogenes which
together
primarily affect the
5. Hemolysins- cause destruction of RBCs
integrity of capillary
i. Alpha: can cause greenish hemolysis
walls.
ii. Beta: complete hemolysis
Exfoliative Toxin  causing sloughing of iii. Gamma: do not cause lysis of RBC
the epidermal layers 6. IgA proteases- split IgA (immunoglobulin)
of the skin leading to 7. Collagenase- Breaks down collagen which is the
SSSS (staphylococcal supportive protein found in tendons, cartilage and
scalded skin bones enabling the pathogen to invade tissues
syndrome) cause by 8. Lecithinase- produced by Clostridium perfringens
Staphylococcus which breaks down phospholipids; Clostridium
aureus or by some perfringens cause gas gangrene
Streptococcus
pyogenes
 It is usually seen in Virulence factors:
newborn babies (skin
reddish and Capsule (for S. Pneumoniae and Klebsiella Pnuemoniae)
sloughing). The  since it evades phagocytosis; yung slimey
epidermal layer is allows bacteria to escape being engulf by
removed in the phagocytes
process.
Surface antigens
Leucocidin  destroy leukocytes,
produced by  V Antigen of Salmonella
Staphylococcus and  K antigen of E. coli
Streptococcus

Diphtheria toxin  produced by
Corynebacterium
which inhibits
 HOST-DEFENSE MECHANISM 2. Ingestion of microbe by phagocyte

Definition of terms: 3. Formation of phagosome

1. Resistance: Ability to ward up disease 4. Fusion of the phagosome with a lysosome to form a
 Non specific: protect against all pathogens phagolysosome
 Specific: protect against specific pathogens;
5. Digestion of ingested microbe by enzyme
antibodies
2. Susceptibility: lack of resistance 6. Formation of residual body containing indigestible
material
2 types host-defense mechanism
7. Discharge of waste materials.
 Non specific:
 Serve to protect the body from a
variety of foreign substances or COMPLEMENT ACTIVATION
pathogens
 first and second line of defense Consequences of Complement Activation:
 Specific: 1. Cytolysis: Due to the formation of a membrane attack
 Are directed against a particular complex (MAC) which produces lesions in microbial
foreign substance or pathogen that membranes.
has entered the body
 third line of defense  The bacterial cell will lies because of the lesions
that be created by the MAC.
2. Inflammation: Complement components (C3a)
trigger the release of histamine, which increases
vascular permeability.
 It will attract macrophages and neutrophils.
3. Opsonization: Complement components (C3b) bind
to microbial surface and promote phagocytosis.

Refer to the reviewer!!!!!
INTERFERONS
Antiviral proteins that interfere with viral
multiplication.
PHAGOCYTOSIS 3 types of Interferons
o Interferon alpha: produced by B
lymphocytes, monocytes, and
macrophages
o Interferon beta: fibroblasts and other
virus infected cells.
o Interferon gamma: activated by T
lymphocytes and NK cells

SPECIFIC HOST DEFENSE MECHANISM

The immune system is the third line of defense against
pathogens; it is a specific host defense mechanism.

Two types of acquired immunity

1. ACTIVE ACQUIRED IMMUNITY
1. Chemotaxis and adherence of microbe to phagocyte
(the adherence of the microbe to the phagocyte will  Natural active acquired immunity: that is
depends on the virulence factor) acquired in response to the entry of a live
 pathogen into the body (i.e., in response to an  IgA: Known as secretory antibodies because
actual infection). It has long duration. they are found in breastmilk, respiratory
 Artificial active acquired immunity: that is and intestinal mucin, saliva, tears, and
acquired in response to vaccines. Its duration vaginal secretions protect these parts of the
for many years; but must be reinforced by body from infectious agents. It exists in
boosters. three for monomer, dimere, trimere. 10-
20% of the total serum immunoglobulin is
2. PASSIVE ACQUIRED IMMUNITY:
compose of IgA; body secretions
 Natural passive acquired immunity: that is  IgD: It is found on the surfaces of the B-
acquired by a fetus when it receives maternal lymphocytes where it acts as a specific
antibodies in utero or by an infant when it antigen receptor.
receives maternal contained in colostrum. Its  IgE: Its activities involved in both the
duration from 6 months- 1 year. resistance to parasites infections and
 Artificial passive acquired immunity: that is hypersensitivity. It is found on the surfaces
acquired when a person receives antibodies of basophils and muscles.; allergies
contained in anti-sera or gamma globulin. Its
duration from 2-3 weeks.; rabies
MICROBIAL CONTROL

Physical/Heat
Two Types of Immunity
1. Moist
Humoral Immunity:
 Pasteurization
- Antibodies and antigens produces by B-cells
 Boiling
- an antibody is a protein produced in response  Autoclaving
to foreign substance (antigen) that will react  Tyndaliization
specifically with that substance. The reaction
between the antibody and the antigen will lead 2. Dry- by oxidation of bacteria/ natutuyo
to destroy the antigen or the pathogen that
 Hot air oven
carry the antigen or inhibit it.
 Incineration

CMI (Cell Mediated Immunity): 3. Radiation- destruction of DNA

- major player is T-cell (kills intracellular  Ionizing- xray, gamma
microbes); nagpproduce ng immunoglobulins  Non ioizing- UV
- pag asa loob na ng katawan yung pathogen
Chemical- denaturation of proteins
- Does not involved production of antibodies
- Controls intracellular pathogens  Alcohols
 Aldehyde
Classes of Immunoglobulin
 Phenols-
 IgG: This is the greatest percentage of  Halogens- heavy metals; iodophore
antibody molecules in the blood, these  Gases- ethylene oxide
globulins combine to small antigen and  Antibiotics
combine and neutralize toxins (antitoxins).
Mechanical
Long lived and crosses the placenta.; pag
chronic pasyente  Filtration
 IgM: is a pentamer (pinakamalaki), has 10 o Air- HEPA/ULTRA
antigen binding sites, first antibodies o Liquid- membrane filter
formed in the primary response to antigens.  Handwashing
Does not cross the placenta.
ANTIBACTERIAL AGENTS  Penicillin
 Vancomycin
Drugs to treat diseases or kill agents of disease It is
 Bacitracin
CHEMOTERAPHY; apply the drugs to infections that will
 Cephalosporins- may beta lactam ring
have selective toxicity.
B. Inhibition of functions of cell membrane; nag
reregulate ng in and out substances, mawawala
yung pagiging semi-permeable ng membrane
2 categories of chemotherapeutic drugs therefore mag sswell or mag shrink pag lumabas
1. Antibiotics mga contents
 polymyxin
- directly produce by microorganism C. Inhibition of protein synthesis-
- ex: penicillin produced by penicillium  Tetracycline (doxycycline)- 30s
 Aminoglycosides (Streptomycin, etc
2. Synthetics lahat ng may mycin)- 30s
 Chloramphenicol- binds to 50s
- antimicrobial drugs synthesize in the lab
 Macrolides (erythron)- 50s
- anti fungal, bacterial, viral, parasitic  Clindamycin- 50s

IDEAL ANTIMICROBIAL
D. Inhibition of nucleic acid synthesis; stop DNA
 High selective toxicity; low toxicity to the host replication
high selective toxicity in pathogens  Rifamycin- stop transcription
 Low propensity for development of resistance  Quinolones (may mga floxacin)- stop
 Not induce hypersensitivities in the host dna rep
 Rapid tissue distribution E. Inhibition of folic acid synthesis
 Free of interactions with other drugs  Sulfonilamide (Bactrim)
 Inexpensive  Trimethroprim

ANTIBIOTICS DRUG RESISTANCE
- Antibacterial Spectrum: scope that drug kills growth of
1. Intrinsic- no target site in bacteria
microorganism
2. Acquired- resistance acquired by mutation is unusual
 Narrow: acts only in one kind of bacteria
 Broad: wide antimicrobial scope; pwede sa -because of mutation
gram – and +
-acquired by r-factor
ANTIMICROBIAL ACTIVITY
-nakukuha sa plasmids
1. Minimal Inhibitory Concentration (MIC)
MECHANISM OF RESISTANCE TO ANTIBACTERIAL
 Min amount of drug required to inhibit growth
1. Antibiotic Inactivation
of bacteria in vitro; least amount of side effects
2. Altered uptake of antibiotics
2. Minimal bacterial concentration (MBC)
 Increased efflux
 Min amount of drug acquired to kill bacteria in
 Decreased permeability
vitro
3. Structurally modified antibiotic

4. Development of altered metabolic pathway
MECHANISMS OF ANTIMICROBIAL AGENTS
AVOID THIS RESISTANCE
A. Inhibition of cell wall synthesis: di na
- avoid unnecessary use of antibiotics
makakabuo ng peptidoglycan, walang cell wall
 Amoxicilin
- full dosage; bacteria is able to mutate pag hindi
complete ang pag inom

- wag gumamit ng topical antibiotics