MIC 205 Immunization and Vaccination Ch 17 PDF

Summary

This document provides lecture notes on immunization and vaccination, covering different types of immunity, historical context, and vaccine development. It discusses naturally and artificially acquired immunity, along with the history of smallpox vaccination.

Full Transcript

MIC 205 - Microbiology
Lecture 15: “It will only hurt for a second! I PROMISE!”
Ch. 17: Immunization and Vaccination

Lecturer:
Patrick Daydif
Office: UCENT 356
Phone: (602) 496-0599
Email: [email protected]
Office Hours: Please refer to Canvas (or by appointment)

The best way to contact me and answer your questions is Face to Face.

Types of Acquired Immunity
Natural
– Active
– Passive
Artificial
– Active
– Passive

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Naturally Acquired Active Immunity
This immunity develops after antigens (e.g., microbial pathogens)
enter the body by natural processes such as infection and, in
response, the body’s immune system forms antibodies and
memory cells.
Length of Immunity Varies
– In some cases, the immunity may be life-long,
smallpox, measles, chickenpox, yellow fever
– In other cases, the immunity may be lost after only a few years
diphtheria, tetanus
– In other cases, even for a lesser period
influenza, pneumonia

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 Naturally Acquired Passive Immunity
When antibodies produced in the body of an
individual (Mother) are naturally transferred
into the body of other individuals (child)
The child develops immunity by receiving
the antibodies.
Certain antibodies (IgA) are also transferred
from mother to infant in breast milk during
nursing.
– These antibodies, called maternal
antibodies, are short lived.
– Most antibodies will remain with the
child for about three to six months.
– There has been examples of the
presence of antibodies circulating a year
after the transfer, but the immunity is
greatly reduced at this point.

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Artificially Acquired Active Immunity
When a carefully chosen antigen (e.g.,
vaccine, chemically altered or inactivated
toxins called toxid) is intentionally
introduced into a body to be immunized.
This immunity is artificial because the
antigens are intentionally or purposely
introduced, and it is active because the
recipient’s immune system synthesizes
antibodies.
Vaccines are now available against many
infectious agents.
– Cholera, tuberculosis, plague,
pneumonia, rocky mountain spotted
fever, smallpox, polio, tetanus,
influenza, measles, rabies
– Toxoid are currently available for
protection against diphtheria and tetanus
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Artificially Acquired Passive Immunity
This is known as antibody therapy, by the introduction
of antibody-rich serum (blood plasma devoid of clotting
factors) taken from diseased individual who has
recovered and given to a susceptible individual
currently with disease.
– Referred to as monoclonal or convalescent therapy.
COVID 19: Bamlanivimab, Casirivimab, and
Sotrovimab
These neutralizing antibodies allow for an immediate
response from the individual with the disease, but the
presence of the antibodies is only 2 to 3 weeks.
Examples of protections from
– Viral diseases such as
Hepatitis B, Chickenpox, COVID-19,
– Bacterial disease such as
Botulism, diphtheria, tetanus, staphylococcal-
poisoning, where toxins are involved in disease
causation.
– Anti-serum or anti-venom is delivered as a form of
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artificially acquired passive immunity

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Passive vs. Active Immunization

Threshold concentration to prevent signs and symptoms

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Vaccines
Historical (Smallpox)
General types of vaccines
– Attenuated (live, weakened)
– Killed (inactivated)
– Subunit / Toxoid
– Vector Based Recombinant

Herd immunity
Method of Administration
Safety Concerns
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History of the SmallPox Vaccine
1500 AD to today: Outbreaks have been documented throughout the world.
– In 1694, marks the death of Queen Mary II/ Ben Franklin lost a son (1736).
– In 1751, London recorded 3,538 deaths, which was a record at the time.
– In 1776, 50% of the Continental army fell ill with small poxes during Quebec's
invasion.
– Last natural out-break was in Somalia in 1977.
– The WHO declared smallpox eradicated in 1980.
17th Century saw the first treatment regimens.
– Use of Variolation
Army, Royalty, & Slaves (Individuals with economic value)
Edward Jenner (1798) documents his uses of variolation and challenges with
smallpox.
U.S. vaccine agency established in 1813
– Congress required the U.S. Post Office to carry the smallpox vaccine for
free.
By 1874, many governments require their citizens to get vaccinated.
1882: Anti-Vaccination arguments spread.
1905: Supreme court case Jacobson v. Massachusetts
1922: Supreme court case Jacobson in Zucht v.King

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 Smallpox Immunization; 19th century
Cowpox pustules used to vaccinate humans. Concept: attenuated live viruses

In 1898 calf lymph became the standard method of vaccination for smallpox in the U.K.

Considerations of a Vaccine
Example: Influenza Virus
– Remember! Virus Subtypes
Determine by the “H” & “N” antigen
on the surface of the virus.
– 15 variations of H and 9
variations of N
The regions in blue are the parts of the
antigen that variety from strain to strain.
– Each flu season, these epitopes will be
different, and therefore the antibodies
from the previous year’s vaccine will not
bind.
The regions in red are the parts of the antigen
or antigen that are conserved from strain to
strain.
– Each flu season, these epitopes are similar
to the previous year virus, and the
antibodies from the previous year’s
vaccine should bind.
– BUT this region does not prevent the
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binding of the virus to the host cell.

Attenuated (live, weakened)
Microbe that has been cultivated under conditions
that disable their virulent properties.
3 methods to design this type of vaccine.
– (1) Remove virulence genes from the microbe.
– (2) Use closely-related but less dangerous organisms to
produce a broad immune response.
(Cowpox will offer immunity for smallpox)

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 Attenuated (live, weakened)
(3) Microbe has been cultivated under different
conditions.
– Culturing the microbe in alternative cell lines with closely
related receptors.
– Microbe will “learn to grow better” nonhuman cell lines.
– When exposed to humans' cell, the microbe will slowly replicate,
& the Immune system will be able to build a strong response

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Influenza “FLU” Vaccine

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Killed/Inactivated Vaccines
Contain killed, but previously virulent, microorganisms that has been inactivated with chemicals
or heat.
– Must not change the shape of the antigens (epitopes) of the microbe.
Remember heat can cause proteins to misfold and change shape.
– The humoral response will create a response to multiple epitopes of the microbe.
Stimulates a TH response that promotes antibody-mediated immunity
Safer
– Organism cannot replicate or mutate
Less Effective
The immune system will only create one humoral response, unless boosters are given.
Must give Multiple doses (“boosters”), to get achieve “active immunity.”

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Subunit Vaccines
Antigenic fragments (protein) of microbe can
create an immune response.
– A small piece of the microbe!
Must be able to elicit an immune response to
protect the individual from signs and
symptoms.
– Protein subunit
Hepatitis B: is composed of the viral
envelope protein
Human papillomavirus (HPV): is
composed of the capsid protein
– Modified toxins
Tetanus, Diphtheria, Rattlesnake
toxoid (dogs).
Stimulate antibody-mediated immunity
Safer: no risk of replication
Less effective requires multiple doses
(“boosters”)

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Vector Based Recombinant Vaccines
The genes for antigens of pathogens inserted into non-
pathogen
Those non-pathogens are injected into an individual
and will express the genes from the pathogen to elicit
an immune response.
Johnson and Johnson uses adenovirus vector vaccine

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Vector Based Recombinant Vaccines
Vaccinia virus (cowpox) infection protects the person against lethal
smallpox infection.
Current research is attempting to clone multiple genes from different
pathogens into Vaccinia virus to offer immunity to
– Smallpox
– Bacillus anthracis (Anthrax)
– Human papillomavirus (HPV)
– Human immunodeficiency virus (HIV)
– Herpes simplex
Vaccinia virus has uniquely large DNA genome for a virus.
– Required to express its genes.
Is required for encoding various enzymes and proteins
Involved in viral DNA replication and gene transcription
Express attachment proteins.
– Researchers need to clone these genes from other organisms to
become antigens for immunity.
This involves molecular techniques such a PCR, DNA isolation, and using
restriction enzymes.

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COVID 19 Vaccines (BioNTech/ Pfizer and Moderna)

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COVID 19 Vaccines

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COVID 19 Vaccines

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COVID 19 US Approved Vaccines
Vaccine Pfizer-BioNTech Moderna J&J/ Janssen
adenovirus vector
Type mRNA vaccine mRNA vaccine
vaccine
BNT162b2, JNJ-78436735,
Other names mRNA-1273
(Comirnaty) Ad26.COV2.S
Doses 2 (21 days apart) 2 (28 days apart) 1
Booster Yes (1-2) Yes (1-2) Yes (1)
Effectiveness Up to 95% Up to 94.1% 52%–81.9%
14 days after 2nd 14 days after 2nd 14 days after 1st
Full vaccination
dose dose dose
Authorized 12/11/2020 & Dec. 18, 2020 &
Feb. 27, 2021 & ?
(EUA)& (Full) 8/2021 2/2022
Eligibility Ages 5 and up Ages 18 and up Ages 18 and up
Cost $ 20 $ 33 $6

No safety concerns were found in animal studies: Studies in animals receiving a Moderna, Pfizer-BioNTech, or Johnson & 22
Johnson (J&J)/Janssen COVID-19 vaccine before or during pregnancy found no safety concerns in pregnant animals or their
babies.

Cancer Vaccines
There are two types of cancer vaccines
– Vaccines that protect an individual from a viral infection that can result in cancer
such as HPV or Hepatitis B (See subunit vaccines)
– Vaccines that treat existing cancer, called treatment vaccines or therapeutic
vaccines. These work to boost the body's immune system, elicit a cell mediated
response known cancer antigens.
MUC-1: Breast
HER-2 /neu: Breast, Ovarian, bladder, Pancreatic, Stomach
IGF1R: Prostate, Breast, Colon
PDL-1: Lung
Sp17: Ovarian, Sperm

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Method of Administration
Direct injection
– Direct to the bloodstream or intermuscular but will not
induce secretory antibodies in the mucus membranes.
– Stimulate Immune response in the lymph nodes
Inhalation or Nasal Spray
– Fast method, Easy, but tends not to make it to the
bloodstream, very little response in the lymph nodes.
– May induce secretory antibodies (IgA) in the mucus
membranes
Oral
– Must not be deactivated by the low pH of stomach
acids & and be able to diffuse from the
intestines/stomach
– May induce secretory antibodies (IgA) in the mucus
membranes
Subcutaneous
– Induced just under the skin (Epidermis)
– Allows for the microorganism to replicate locally and
NOT throughout the body 24
– Can induce a systemic immune response

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 Importance of Administration Method
Direct injection of a vaccine will place the antigens in the
tissues and elicit an immune response in the lymphatic
system.
The drawback to this method is it will allow the microbe
into the body, and the immune system will start its
protection in the lymphatic system.
Inhalation and Oral vaccine will place antigens in the mucus
membrane.
This could elicit a localize response
by M-cell and the Peyer’s patch.
This would active B-cells to produce
IgA antibodies in the mucus membrane,
therefore, prevention of the microbe
crossing the mucus membrane.
The drawback to this method
mucociliary clearance of the vaccine,
thus, low level response.

Vaccine Safety & Problems
General side effects
– Interferon Response
Residual virulence
– Attenuated vaccine
Vaccine Recalls
– Gardasil ( HPV) and COVID-19 J&J vaccine
Contamination
– 2004 flu vaccine contamination, Thimerosal as a bacteriostatic agent
Public misconceptions
– Jenny McCarthy announced that her son was diagnosed with autism due to the preservation agent in MMR
vaccination.
– Andrew Wakefield
This has been rejected by scientific studies, with McCarthy's claims that vaccines cause autism are not supported by any
medical evidence (National Institute of Mental Health)
The original paper (Mid 90’s) by Andrew Wakefield formed the basis for her claims but was based on manipulated data and
fraudulent research.
Even with his articles retracted, Wakefield had planned a venture to profit, plus McCarty taking to media platforms has now led
to the MMR vaccine scare.

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Vaccine Safety & Problems
Stability
– Does the Vaccine need refrigeration?
1955 Salk Polio vaccine (Inactivated)
1962 Sabin polio vaccine (Attenuated)
– COVID 19
Pfizer: Requires: -80˚ for storage and
last at 4˚C for 30 days
Moderna: Requires: -20˚ for storage
and last at 4˚C for 30 days
J&J Requires: 4˚C storage
Allergic reaction
– Gelatin/MMR, Eggs/ Influenza
Research Cost/Government
– FDA, CDC, WHO
– 1 attempt cost about 1.1 billion per
drug;1/250 will make it market.

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 Does Everyone need to be Vaccinated?
Herd immunity
– Describes a type of immunity that
occurs when the vaccination of a
portion of the population (or herd)
provides protects to unprotected
individuals.
More difficult to maintain a chain
of infection when large numbers of
a population are immune.
The higher the proportion of
individuals who are immune, the
lower the likelihood that a
susceptible person will contact an
infectious individual.

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Herd Immunity thresholds for Protection
Herd immunity
Disease Transmission
threshold
Diphtheria Saliva 85%
Measles Airborne 94%
Mumps Airborne droplet 86%
Pertussis Airborne droplet 94%
Polio Fecal-oral route 86%
Rubella Airborne droplet 85%
Smallpox Social contact 85%
COVID-19 Airborne droplet ?70%?

Source::History and Epidemiology of Global Smallpox Eradication From the
training course titled "Smallpox: Disease, Prevention, and Intervention". The
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CDC and the World Health Organization.

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