Microbiology Exam 3 Review PDF

Summary

This document is a microbiology exam review, containing a set of quiz-style questions regarding topics such as disease transmission, the role of Aedes aegypti in the YF transmission cycle, and the steps of the RNAi pathway. The document aims to help students prepare for a microbiology exam.

Full Transcript

Microbiology Exam 3 Review
★ Quiz Questions
○ To classify an arthropod as a vector of disease, it must
Be shown to become infected when feeding on a host that has an
infectious agent present in the blood
Associate and feed on host under natural conditions
○ Which of the following terms describes non-human primates in the YF virus
transmission cycle?
Enzootic host
○ Which of the following terms describes Aedes aegypti in the YF transmission
cycle?
Vector
Bridge vector
○ Which organisms are part of the sylvatic (enzootic) disease transmission cycle of
YF virus?
Non human primates
Aedes aegypti
○ Which organisms are part of the epidemic transmission cycle of YF virus?
Humans
Aedes aegypti
○ Which of the following best describes the route of viral infection within the
mosquito?
Food canal, midgut, hemocoel, saliva
○ Which of the following best describes the role dicer plays in the RNAi pathway?
Binds and cuts dsRNA into small pieces
○ Which of the following describes the final step of the RNAi pathway?
Any sequence that complementary binds to the ssRNA loaded into the
RISC complex will be degraded
○ Which of the following historical events was heavily influenced by YF?
Spanish American War
Louisiana Purchase
○ YF can be directly transmitted from person to person
FALSE
○ SIT vector control strategy relies on the release of sterile ___ mosquitoes into the
environment
Male
○ The RIDL vector control strategy relies on a dominant lethal gene being
expressed during ___ mosquito development
Female
○ Which of the following mating pairings would result in cytoplasmic
incompatibility in mosquitoes due to a Wolbachia infection?
Uninfected female mates with an infected male
Infected MALE w/ non-infected FEMALE
○ What flavivirus protein is responsible for receptor binding?
E
○ Flavivirus particles bind at the ___
Endosomal membrane
○ What statement best describes the initial flavivirus translation event?
10 viral proteins are first translated together as one polyprotein from one
transcript
After translation the proteins are cleaved into individual
components
○ Flavivirus particles are assembled at the ___
ER
○ A mutation in the YF virus genome occurs that prevents the cleavage of prM in
the trans-golgi network. How does this mutation impact the virus?
The released particles will not be able to fuse with the endosomal
membrane
○ Cyclization motifs in the flavivirus genomic RNA ___
Inhibit translation of genomic RNA and promote replication ( – strand
production)
○ Without the cyclization motif of the flavivirus genome ___
Viral polymerase and ribosome risk colliding (and premature abortion of
replication and translation)
○ Which cells are typically the first cells to be infected during a dengue virus
infection?
Langerhan cells
○ What is the PAMP that serves as the initial target site recognized during a dengue
virus infection?
Carbohydrate attachments present on E and M
○ The jaundice associated with a YF viral infection is a direct result of __
Damage to the hepatocytes due to viral replication
Damage to the hepatocytes due to activation of eosinophils
○ Which antibodies are responsible for enhancing disease progression in ADE?
Non-neutralizing antibodies
○ What best describes the vaccine format used for the YF virus?
Live attenuated vaccine
○ What best describes the vaccine format used for the current limited use for
Dengue virus?
 Recombinant chimeric vaccine
○ The generation of a vaccine to Dengue virus is problematic because __
A vaccine must be effective against all 4 serotypes
○ The main cause of severe malaria is __
P. falciparum
○ Which of the following is capable of transmitting Plasmodium?
Anopheles gambiae
Anopheles freeborni
Anopheles stevensi
○ Mitochondrial DNA sequencing suggests the P. falciparum most likely evolved
from __
A cross-species transmission event from gorillas
○ Immediately after the mosquito bites that transfers Plasmodium into the blood of
its human host, ___ first invades the ___ in order to establish replication within
___
Sporozoites
Kupffer cells
Hepatocytes
○ Which feature on P. falciparum is responsible for binding to erythrocytes?
PfEBA175
○ Which of the statements describes the role of PfEMP1?
It is a protein expressed on the surface of the erythrocyte causing it to stick
to the endothelial lining of the blood vessel
○ Which of the following is responsible for the maturation of Plasmodium gametes?
Drop in temperature from 37C
○ Which of the following are sites of Plasmodium sexual reproduction?
Mosquito midgut
○ Which developmental stage of Plasmodium is part of the mosquito developmental
cycle?
Ookinete
Gametocyte
○ Which developmental stage of Plasmodium is present in the mosquito salivary
glands?
Sporozoite
○ Which developmental stage of Plasmodium is released from the liver schizont?
Merozoite
★ Key Points
○ Lecture 14
Define disease vector
 Any agent that carries and transmits a pathogen to another living
organism
Agent for transmission
Identify important characteristics for disease transmission
Vectors influencing disease transmission differently
○ Sporadic introduction to population
○ Consistent circulation
Constantly always carrying pathogen
Whenever we have contact with vector, have
possibility for infection
○ Vector drives transmission
Identify different arthropod vectors (i.e. mosquitoes, flies, fleas, ticks)
Hematophagous
○ Blood meals
In saliva, there are pathogens present
Transmission through bites
Species important when looking at vectors of disease
○ Anopheles – Malaria
○ A. aegypti – YF and Dengue flaviviruses
Define epidemic vs epizootic vs enzootic cycles of disease transmission
Epidemic
○ Increase in incidence/prevalence of infection within a
human population
Human
Aedes aegypti
Endemic
○ Stable incidence of of infection within a human population
Epizootic
○ Increase in incidence/prevalence of infection within an
animal population
Enzootic
○ Stable incidence of infection within an animal population
Non-human primates
Aedes aegypti
Describe the role of a bridge vector in transmission cycles of disease.
Bridge vector
○ Acts as a link between transmission across different animal
hosts (primates & humans)
Primates and humans are unable to directly infect
each other, but the mosquitoes can carry the virus
 Be able to explain simple and complex transmission cycles of diseases
based on diagrams.
Simple transmission cycle
○ Pathogen directly transmitted from one host to another
Infected mosquito bites human
The infected blood of a human will then infect other
mosquitoes
Cycle continues
○ YF and Dengue transmission
Epidemic transmission in conjunction with endemic
transmission via non-human primates (enzootic
host)
Complex transmission cycle
○ Pathogen transmitted through multiple intermediate hosts
or vectors
○ FOR EEEV
Enzootic host – passerine bird
Enzootic vector – mosquito
Epizootic host – pheasant
Epizootic vector – mosquito
Dead-end host – humans & horses
Do not replicate the EEEV virus enough to
keep up with transmission
○ Makes it harder to find the cause/beginning of transmission
Describe different factors that impact vector borne disease transmission
Climate & weather
○ Standing water – breeding ground
○ Rain or humidity
○ Warmer temperatures – increase life cycles
Human environment
○ Sanitation
○ Limited access to healthcare
Vector & host population/availability
○ Amount of vectors present in an area
○ Amount of hosts (ex. primates or humans)
Increase transmission
Travel
○ Infected humans traveling can introduce pathogens to new
areas
Describe the steps required for vector incrimination
 Vector incrimination
○ Vector must associate with & feed on vertebrate host under
field conditions
Seasons and location of arthropod activity may
coincide with host infection
○ Naturally infected vectors must be consistently recovered
from the field
○ Vector must be shown to become infected when feeding on
a host known to be infected
○ Vector must be shown to transmit pathogen via controlled
conditions
Compare and contrast the three main virus families transmitted by
mosquitoes
Flaviviruses
○ ssRNA positive strand
○ Enveloped
○ Icosahedral
YF virus, Dengue, West Nile, Zika
Alphaviruses
○ ssRNA positive strand
○ Enveloped
○ Icosahedral
EEEV
Bunyaviruses
○ ssRNA negative strand
○ Enveloped
○ Pleomorphic
La Crosse, Rift Valley
Describe the mosquito developmental life cycle and how it impacts
disease transmission

Blood meal required for egg development
○ Female mosquito transmits infection
Eggs are laid on surface of still water
Larvae develop aquatically near the surface of the water
Compare and contrast the male and female mouthparts and how it impacts
disease transmission
Anatomy
○ Dipterans – true fly, two-winged insect
○ Mouth parts, antennae, and odor receptors differ between
sexes
Even what they feed on!
Females
○ Feed on nectar and blood
Attracted to warmth, CO2, and sweat
○ Mouthparts designed to pierce skin
Males
○ Feed on nectar
Explain the steps involved in a mosquito bite and how it impacts disease
transmission.
Mosquito bite
○ Mouth probes until blood vessel is found
○ Saliva is injected
Assists with uptake of blood
Contains anti clotting factors, vasodilators, and
antiplatelet factors
○ Mast cells are stimulated that leads to histamine release
Swelling occurs at the site of the bite
 Explain the pathway of infection in mosquitoes (where does the virus go
from entry to exit)
Virus taken up via mouthpiece & food canal
Enters the midgut
Infects midgut and breaches barrier
Transports through the hemocoel to the salivary glands
○ Hemocoel possess a lot of immune functions
Infects salivary glands and grows to high titers
○ See the highest amount of replication here
○ An amplifying infection
Explain the pattern of infection used within the vector and why this pattern
specifically beneficial for a vector of disease
Acute
○ High level of replication with rapid resolution (days)
Chronic
○ Constant replication at low levels OR high levels with
immune evasion
Latent
○ High level of replication followed by almost complete
acquiescence/dormancy
Can reactivate
ALLOWS FOR CONSTANT TRANSMISSION
Name the three major pathways involved in mosquito immunity
RNAi (RNA-interference) – primary antiviral defense
Toll
Imd
Explain how RNAi works to prevent viral infection
RNAi (prevents viral infection)
○ Made during replication of the viral genome
○ Dicer recognizes the dsRNA and cuts it up into pieces
○ One strand is loaded into the RISC complex
(RNA-induced silencing complex)
Argonaute = main component
○ Complementary base-pairing of the RNA strand targets it
for destruction
By Argonaute associated RNase activity

○ Lecture 15
Explain how yellow fever spread to the Americas
 Spread during the forced expatriation (removal from home
country) of West Africans through the slave trade
○ Needed more workers because native workers were being
decimated by smallpox
YF virus endemic in Africa
○ Disease in native Africans are relatively mild
HOWEVER, the resistance of African slaves to the disease in
comparison to the severe disease in Europeans & Native
Americans increased demand for MORE slave workers
○ A cycle
The late 18th century of YF epidemics caused government to shut
down
Explain how yellow fever impacted historical events such as the Louisiana
Purchase and the Spanish American War
1801 – France losing Haiti due to YF and revolution
○ Uprising of African workers in France-occupied Haiti
Napoleon sends large force of troops to stop
uprising
27,000 French troops die of YF, while
revolutionaries are not affected
○ Haiti gained independence!
1803 – Louisiana Purchase
○ Napoleon sells the Louisiana Purchase
Due to massive losses from Haitian uprising
Loss of capital
Increased need for resources in Africa &
Europe
Mid-late 19th century – Outbreaks along Mississippi River
1898 – Spanish-American War
○ YF endemic in Cuba
○ Led to the establishment of US Army YF Commission
(1900)
Explain how the mechanism of yellow fever transmission was discovered
1878 –
○ Patrick Mason demonstrated transmission parasite causing
filariasis by mosquitos
Mosquitoes are vectors that transmit infectious
agents
1892 –
 ○ Ivanowsky found that tobacco mosaic disease was
transmitted by an agent smaller than bacteria
Agent was virus (but not discovered yet)
1901 –
○ Walter Reed (head of YF Commission in Cuba)
demonstrated that the agent was causing YF could pass
through filters & was present in the blood of infected
individuals
Self inoculated using mosquitoes that had bitten
infected individuals
No symptoms occurred
Used mosquitoes that had bitten an infected person
12 days before
Got sick and died
Concluded transmission caused by
mosquitoes
Identify the vector of flavivirus infection (Genus species)
Aedes aegypti
Explain the factors that make a pathogen eradicable
Limited host range
○ Only humans or a defined vector
Harder to eradicate when there are multiple hosts
Mechanisms of transmission intervention (vaccine)
Has been eliminated in a smaller geographic area
Significant public health burden
○ Many incidences/deaths have affected other circumstances
Economy!
Makes financial sense to the countries involved
Explain why yellow fever is not a good candidate for eradication
Has multiple host ranges
○ Enzootic cycle w/ non-human primates
Describe the vaccine design and efficacy for yellow fever
Vaccine development
○ 1937 by Max Theiler
○ Attenuated by
Chick embryo fibroblasts
If humans could be vaccinated or eradicate Aedes aegypti, then
transmission cycle could be broken
○ No one knew about the sylvatic cycle until the 1960’s
 Explain the advantages and disadvantages of using DTT as a control
method for yellow fever
DDT – chemical spray
○ Began in 1946 for malaria – US was malaria free by 1949
Advantages
○ Helped to reduce cases of YF and malaria
Disadvantages
○ Environmental effects on birds and shellfish
DDT banned in US in 1972
Stockholm Convention led to global restriction in
2004
Still used in emergency situations
Explain the advantages and disadvantages of using SIT to control
flaviviruses
SIT – sterile insect technique
○ Males exposed to non-lethal levels of radiation or mutation
causing chemicals in the germline
Males are sterile bc progeny are lethally mutated
Explain the advantages and disadvantages of using RIDL to control
flaviviruses
RIDL – release of insects carrying a dominant allele
○ Mosquitos engineered using transposon-like gene elements
where a “lethal” gene is expressed only in females during
development
No adult females thus no blood feeding
Explain the state of yellow fever now and what factors allow the problem
to persist
YF has now spread to many other countries
○ Inconsistent vaccine coverage
Supply constraints & lack of financial resources
○ Urbanization (mosquitoes thrive in densely populated
areas)
○ Sylvatic transmission cycle (reservoir in animal
populations; enzootic)
○ Increased traveling
Describe how Wolbachia infected Aedes is used to control flaviviruses
Wolbachia
○ Gram negative bacteria
○ Endosymbiont (live in hosts)
Transmitted from mother to child
 Causes cytoplasmic incompatibility
○ Embryos die who are from uninfected F mating with
infected M
If infected F mate with either infected or uninfected M…
○ Produce offspring but have decreased life spans
○ Reduce viral replication and thus lowers TRANSMISSION
Identify the regions of the world most at risk for yellow fever infection
Africa (West Africa), South America
Describe the factors contributing to the re-emergence of yellow fever in
sub-Saharan Africa and South America
Loss of vector control programs due to banning DDT
Intrusion of sylvatic life cycle
Failure to immunize at-risk populations (delivering vaccine)
Economic & political instability – particularly due to wars
○ Lack of physical access & funds

○ Lecture 16

Describe the hierarchical relationship between Flaviviridae family,
Flavivirus genus, and species.
4 genre
○ Flavivirus
○ Pestivirus
○ Hepacivirus
 ○ Pegivirus (proposed)
All similar in virion morphology, genome
organization, & replication strategy
Exhibit diverse biological properties & lack
serologic cross-reactivity
Give examples of the major members of Flavivirus
Yellow Fever
Dengue (types 1-4)
West Nile
Tick-borne encephalitis
Japanese encephalitis
Compare and contrast the different host, diseases, and vectors associated
with Flavivirus
Yellow Fever
○ Monkeys and humans
○ Hemorrhagic fever
Dengue
○ Monkeys and humans
○ Fever, rash, hemorrhagic fever
West Nile
○ Birds and humans
○ Fever, rash, arthralgia
Tick-borne encephalitis
○ Rodents, birds, and humans
○ Encephalitis
Japanese encephalitis
○ Birds, pigs, and humans
○ Encephalitis
Describe the structure of the Flavivirus virion
Icosahedral virus
T = 3 (180 subunits)
Lipid envelope
Proteins
○ E dimer = responsible for attachment
○ M protein
○ Capsid protein
Describe the viral and host proteins involved in flavivirus attachment
ATTACHMENT
E protein
○ Responsible for attachment and fusion
 ○ Binds to cellular receptor
Not a specific receptor, but can use
Lectins
○ Bind sugars
Integrins
○ Connect cells together
Broader host cell receptor allows the virus to infect multiple hosts!
Describe the class II fusion mechanism used for entry (what is the fusion
protein, what does it look like pre and post fusion, where is the fusion
peptide located, where does fusion occur, what is the trigger for fusion)
ENTRY
○ Receptor-mediated endocytosis (virus taken up into
endosome)
○ pH will drop and trigger fusion with endosome
Causes conformational change
Class II fusion mechanism
○ E protein responsible for fusion
Start as a dimer & end as a trimer
○ Pre-fusion
E protein is a dimer that lies on the surface of the
viral membrane
○ Trigger
Low pH within endosome
Induces a conformational change & dimer
reorganizes into a trimer
○ Post-fusion
E protein becomes a trimer and each monomer
extends and stabilizes the fusion core → draw
endosome and viral membrane together
Fusion peptide
Piece of the E protein
Hydrophobic, so it will bury internally at
dimer interface
Feature Table (Class I influenza v. Class II dengue)

Feature Class I Class II

Conformational Metastable fusion Metastable dimer to
change during trimer to stable stable fusion trimer
fusion fusion trimer
 Predominant alpha-helix beta-sheets
secondary structure
of fusion protein

Post-fusion Trimer of hairpins Trimer of hairpins
structure w/alpha helix coil composed of
beta-structure

Maturation to Proteolytic Proteolytic
pre-fusion state processing of fusion processing of
through – protein companion protein

Fusion peptide N-terminal peptide Internal loop at
location buried in trimer fusion protein tip –
interface capped by dimer
interaction

Explain how the genome organization allows for immediate translation of
a polypeptide
+ sense genome (mRNA sense)
○ Able to be translated immediately bc it does not have to be
transcribed
Translation outsourced to host machinery
Explain the difference between the initial polypeptide and the mature viral
proteins
Viral genome
○ Contains a cap
○ Has no poly A tail → poly A tail usually helps with
stopping translation
INSTEAD, use stem-loops of RNA
Polypeptide precursor
○ 1 single polypeptide containing multiple proteins
Mature proteins
○ Viral and host proteases will cleave polyprotein to make the
multiple mature proteins
Explain the problem between translation and replication that arises from
being a positive sense genome.
+ sense RNA will be translated and replicated in the cytoplasm
○ First ribosomes will translate (make polypeptide) from 5’
end
○ At the same time, some polyproteins that have been created
will start to replicate on the 3’ end
 This can end of CLASHING
The mRNA and the + strand transcript
Explain how flaviviruses use the circularization motif to resolve this
problem.
Specific RNA sequences at the ends of the genome contain
cyclization motifs that will pair together and form a loop (bring 5’
and 3’ together)
○ Viral replicase host factors stabilize terminal interaction
Loops causes either ribosomes or replications to bind and prevent
the other from binding
○ For replication, the proteins bind to cyclization motif and
prevent ribosome binding – allows replication but NOT
translation
Identify the viral protein responsible for replication
Viral polymerase → NS5
Describe the steps and location of viral assembly and budding
ER
○ Recruit newly formed genomes which interact with capsid
protein (C) to form viral cores
Viral glycoproteins are also recruited and anchor to
the ER membrane (E and prM)
○ Immature virion is created through budding of the virus
into the ER lumen
Golgi
○ Immature virions transported via vesicles to Golgi through
secretory pathway
○ prM proteins undergo conformational change & cleaved by
furin → creates mature M protein
Also results in rearrangement of E protein into
mature, infectious form
Cell Membrane
○ Mature virions packaged in vesicles and travel to cell
membrane
Exit via exocytosis
Do NOT bud from plasma membrane –
happens in ER
Explain the difference between viral glycoprotein modifications in the
mosquito vector and the human host.
In humans = complex sugars are added during glycoprotein
modification
 ○ Complex sugars allow virion a higher rate of immune
evasion & receptor activation
In mosquitoes = high mannose sugars are added
○ Simpler sugars allow virion to have efficient replication
and transmission
Describe the role of prM in viral infection and the importance of the
cleavage of prM
prM = inhibits premature fusion in the low pH environment of the
Golgi
○ (trans-golgi network) Furin protein will cleave the pr
peptide to form the mature M protein
If the prM is not cleaved, the released particles/virus are unable to
fuse with the endosomal membrane

○ Lecture 17
Describe the basic symptoms associated with yellow fever and dengue
viruses.
YF virus
○ Symptoms
First – fever, chills, back pain, nausea, mild
hemorrhaging, & nose bleeds
Second – short remission (6-24 hrs)
Third – symptoms recur w/ more vomiting (black)
and jaundice (more toxic stage)
Fourth – increased hemorrhaging (bleeding)
Death in 20-50% of cases 7-10 days
following onset
○ Recovery
Prolonged convalescence (recovery) with severe
fatigue
Takes months
Dengue virus
○ Dengue Fever
Symptoms
First – headache, fever, eye pain, upper
back pain, rash (4-6 days after infected)
Second – muscle/joint/bone pain, vomiting,
weakness, exhaustion
Third – possible hemorrhaging (mild)
○ Not lethal but debilitating
 ○ Dengue Hemorrhagic Fever & Dengue Shock Syndrome
(2nd infections)
Symptoms
Similar to DF plus vascular leakage
○ Vascular leakage causes drop in BP
and “shock”
Hemorrhaging can occur internally &
externally
Recovery
Spontaneous OR
w/ electrolyte therapy
○ Death in 1-10% of cases
Explain steps involved in the initial flavivirus infection and how it
spreads, paying close attention to the type of cells involved.
Initial infection (epidermal layer)
○ Mosquito probing releases virus into epidermis &
bloodstream
○ Infection of Langerhans (immune APC) cells via DC-SIGN
recognition of high mannose glycoproteins
Mosquito cells add the glycans to receptors
○ Langerhans cells migrate to lymph nodes
Have high concentration of macrophages that can
be infected by flavivirus (YF or Dengue)
○ Virus released into bloodstream & infect other tissues
(VIREMIA)
Can be picked up by mosquitoes during a blood
meal
Glycan addition to proteins (modifications in Golgi)
○ Initial infection dependent on virus coming from mosquito
host
Adds high mannose additions (allow recognition)
COMPARE TO HUMANS
○ Which add complex sugars to virions
Explain the steps involved in yellow fever pathogenesis, paying close
attention to the type of cells involved and how it is resolved.
Kupffer cells infected (liver APCs) → causes infection of
hepatocytes (liver cells)
○ Causes cytokine production and signals eosinophils
Eosinophils = immune cells associated with
parasitic infection/allergic responses
 Eosinophil activation causes hepatic degradation & jaundice
○ Major symptom of liver dysfunction
○ Jaundice – caused by leftover bilirubin
Describe the yellow fever vaccine design, paying close attention to the
type of vaccine format used.
Disease resolved via neutralizing antibody response – only get
infected once
○ Ab bind to virus – prevent infection – target for uptake by
macrophages
Vaccine
○ 17D live attenuated virus
Derived from Asibi strain by 203 passages in
non-primate cells (chicken)
32 amino acid changes – mostly in E protein
Loss of virulence in humans
Inhibited ability of virus to infect
mosquitoes
Explain the differences between classic dengue fever and dengue
hemorrhagic fever and shock syndrome, both in terms of symptoms,
lethality, and cause.
Pathogenesis
○ Macrophages are primary site of replication
Dengue Fever (LESS SEVERE)
○ Self-limiting infection – resolves on its own
Macrophages infected & endothelial cells of small
blood vessels
○ Symptoms become apparent 2-7 days post infection
Headache, fever, nausea, vomiting, bone pain,
weakness, exhaustion
○ Children to appear to suffer less severely than adults
Dengue hemorrhagic fever (DHF) – MORE SEVERE
○ Lethality rate of 1-10%
○ Caused by all 4 serotypes
○ Fever, increased hemo-concentration, low platelet count
○ Spontaneous hemorrhaging
Define the difference between neutralizing vs non-neutralizing antibodies.
Neutralizing antibodies
○ Bind to virus
○ Prevent infection (ex. attachment & fusion of virus)
○ Recruit macrophage & prevent it from getting infected
 Non-neutralizing antibodies
○ Aid in amplification of infection
○ Recruit macrophages but do not protect them from getting
infected by the virus
Explain the role of ADE in dengue virus infection and how it impacts
pathogenesis and vaccine design.
Antibody dependent enhancement (ADE)
○ Antibodies for one serotype may bind but NOT neutralize
another serotype
○ Outer components of virus less conservative
antibodies do not cross-react fully
○ DEN-Ab complexes allow uptake by macrophages w/Fc
receptors
Assista infection increasing kinetics of virus
replication & viral load
○ Vascular permeability increased due to inappropriate
cytokine release
Explain why we have seen an emergence of DHF.
Human population growth – increase vector contact
Urbanization w/poor infrastructure – favor vector breeding
Air travel – allows movement of viremic humans & dissemination
of multiple serotypes
Hyperendemic areas – increased chances of serial infection
○ ISSUE
4 serotypes of DENV against which to vaccinate
Compounded by problem of antibody-dependent
enhancement of disease leading to DHF (dengue
hemorrhagic fever)
Explain the different vaccine design strategies used for dengue virus,
focusing on the different vaccine formats and the challenges for each.
Subunit vaccines using E glycoprotein from different serotypes
○ Protein expression and purification in both bacteria and
eukaryotes
HOWEVER does not stimulate robust response
Attenuated virus vaccine
○ Passage of Dengue in non-human tissue culture cells –
leading to attenuation in humans
HOWEVER, concerns about incomplete immune
response and issues with production
Recombinant noninfectious subviral particles
 ○ Expression of just surface glycoproteins in cells – lead to
production of virus-like particles that do not contain genetic
material (noninfectious)
HOWEVER, can produce antibodies but not a
complete immune response
DNA vaccines
○ DNA only driving production of E protein
HOWEVER, problem w/ number of doses needed
for sero-conversion & need to express 4 different
Dengue proteins
Recombinant chimeric viruses
○ Introduction of major antigens from Dengue into attenuated
virus backbone (like YF vaccine virus)
HOWEVER, Dengvaxia only licensed vaccine
(many restrictions)
Have to carefully balance response to all 4
serotypes of Dengue

○ Lecture 18
Describe the mechanism of transmission of malaria and how it was in
discovered
Malaria – “bad air”
○ Caused by Plasmodium parasites
Plasmodium spp. thought to co-evolve w/humans
P. falciparum more recent human pathogen
being introduced between 10-50k years ago
Charles Laveran – French physician
○ Observed parasites in RBCs of patients suffering from
malaria (late 19th century)
Sir Ronald Ross
○ Demonstrated mosquitoes vector of malaria using birds
Malaria has played significant roles in wars (US troops in WWII)
○ Numbers increasing due to drug resistance
○ Sporadic imported cases in malaria free countries
Describe global distribution of malaria and who is most at risk
Sub-Saharan Africa
Southeast Asia
South Asia
Central & South America
○ Children most at risk
 Describe the clinical symptoms of malaria
Headache
Fever
Shivering
Arthralgia (joint pain)
Vomiting
Hemolytic anemia
Jaundice
Hemoglobinuria – oxygen and hemoglobin in urine
Retinal damage
Convulsions
○ Periodicity to the symptoms
○ Symptoms change and flow
SEVERE FORM
○ 6-14 days post infection (w/ Plasmodium falciparum)
Enlarged spleen & liver
Severe headache
Restricted blood flow to brain
Renal failure
Seizures
Opisthotonus (muscle spasm)
Uncoordinated eye movement
Coma
Define apicomplexans (and explain what it has to do with Plasmodium)
Phylum of protists
○ Obligate parasites evolved from a free-living
photosynthetic ancestor
Apicoplasts
○ Organelle derived by an endosymbiotic event
○ Required for fatty acid biosynthesis
○ Non-photosynthetic BUT believed to have evolved from
red algae
List the five major Plasmodium spp. associated with malaria in humans.
P. falciparum
P. vivax
P. ovale
P. malariae
P. knowlesi
Explain the origin of Plasmodium falciparum
Most severe form
 ○ Thought to diverge from P. reichenowi
Consequence of human-chimpanzee speciation
○ NOWADAYS
Came from cross-species transmission event from
gorillas
From mitochondrial DNA sequencing
List the three Anopheles spp. associated with the most transmission.
Anopheles is associated with Plasmodium virus transmission
○ 460 characterized species
100 can transmit human malaria
30-40 are predominantly responsible
Most responsible for transmission
○ An. gambiae
○ An. stevensi
○ An. punctulatus
Explain the general Plasmodium life cycle and how it relates to
transmission (next lecture will have much more detail).
Programmed developmental cycle
Mosquito essential for cycle
○ For TRANSMISSION and DEVELOPMENT
Explain the current economic and societal concerns facing malaria
Malaria linked with poverty (not symptom but cause)
○ Contributes to
high death rates
low life expectancy
reduction in workforce
impairment of cognitive abilities in children
○ High impact on health expenditure
Loss of at least $12 billion per year to African
Nations
○ Problems can be compounded by substandard or counterfeit
drugs
Approx. 1/3 drugs in Sub-Saharan Africa and
Southeast Asia are counterfeit or substandard
○ Historically, hard to get buy-in from non-malaria nations to
assist w/ funding, research, prevention, and treatment

○ Lecture 19
Describe the Plasmodium falciparum genome.
14 chromosomes, 23 MB
 Haploid EXCEPT at zygote stage in mosquito
Low prop. of spliced mRNAs
60% of genes have no assigned function
○ (only know 40% of functions)
Low # of metabolic & amino acid synthesis genes
○ Host cell dependent
High proportion of genes involved in immune evasion
○ Co-evolved with humans
○ Prevent host from clearing the parasite from the body
Draw a flow chart of the developmental cycle of Plasmodium within both
the human and mosquito host.

Describe the initial infection within humans, paying to close attention to
the developmental form and the importance of the apical complex in
movement and invasion.
Initial infection
○ 12-24 sporozoites (incoming infectious parasite) injected
during blood meal
Gliding motility to help with infection
Mediated by actin-myosin motors on
exterior
○ Push way through blood vessels into liver
Requires secretion of proteins from apical complex
 Proteins secreted change throughout life
cycle
○ Apical complex
Polar ring
Rhoptries
Micronemes
Define the sporozoite
Infective stage of Plasmodium that is transmitted to humans from
mosquitoes
○ Travels to liver cells where it develops further
Describe the steps involved in P. falciparum infection of the liver,
focusing on the progression of development.
Infection of the Liver
○ Move through Kupffer cells to access underlying
hepatocytes
Kupffer cells – resident liver macrophages that are
involved in immune response
Infection of Hepatocytes
○ Sporozoites secrete apical complex proteins
Help form parasitophorous vacuole
Vacuole protects from intracellular attacks
○ Sporozoite undergoes asexual reproduction into merozoites
in the liver schizont
Schizogony – form of production
○ SPOROZOITE → SCHIZONT → MEROZOITE
Describe the role of the parasitophorous vacuole and schizont in
development.
Parasitophorous vacuole
○ Help to protect from intracellular attacks
Schizont
○ Multinucleate form of parasite that develops in hepatic cells
From asexual reproduction of sporozoite
THEN segments into merozoites
Define the merozoite.
Developmental form of parasite that infects RBCs
○ Produced by schizogony
Describe the steps involved in P. falciparum infection of the red blood
cell, focusing on the progression of development.
Merozoites are released into bloodstream and bind & enter RBCs
Teardrop shape
 ○ Interact between sialic acids & peptides on erythrocyte
glycophorin A and 175-kd erythrocyte-binding antigen
(PfEBA175) on the merozoite
Merozoite interacts w/RBC via PfEBA proteins on its surface
○ Reorients and binds at its apical end (smaller side)
○ Forms a junction and secretes proteins that evade RBCs
ALSO forms the parasitophorous vacuole for entry
Merozoite develops into a trophozoite
○ Secretes proteins into host RBCs
○ PfEMP1 (Plasmodium falciparum erythrocyte membrane
protein 1) made by parasite & secreted
Creates “knobs” on surface of RBCs (severely
distorted RBC)
PfEMP1 binds RBCs to endothelial cells in
blood vessels
Define the trophozoite.
Activated stage of development where it remodels the RBCs
○ Once RBCs are stuck to the endothelial lining → reduce
blood flow, matures BACK into a SCHIZONT
○ Asexual reproduction → produces 16-20 merozoites
RBC ruptures and releases many merozoites (to
infect more RBCs)
Define the gametocyte.
Sexually committed merozoites that produce male & female
gametes (gametocytes)
○ Critical for infection of mosquito
Describe the role of PfEMP1 in infection and pathogenesis.
Creates “knobs” on the surface of RBCs
○ Binds to endothelial cells on blood vessel lining & reduce
blood flow
Describe the initial infection within the mosquito, including what happens
to the merozoites and gametocytes.
Infection of Mosquito
○ Gametocytes
Produced in human bloodstream
Do not actively invade RBCs or cause
symptoms
○ Pretty much dormant
Taken up by mosquito during blood meal &
deposited in midgut
 Drop in temperature in mosquito (compared
to human) causes gametocytes to develop
into GAMETES
○ Will become fertilizes and produce
zygotes – ONLY DIPLOID FORM
○ Merozoites
Also taken up by mosquito, but will not survive in
the midgut for very long
Define the ookinete.
A diploid zygote (mature) that undergoes meiotic nuclear division
forming haploid nuclei
○ Develops in midgut 5 hours post blood meal
Describe how the ookinete in the midgut progresses to the sporozoite in
the salivary glands.
Ookinete (midgut) → Sporozoite (salivary glands)
○ Ookinete is formed by the fertilization of male and female
gametes
Migrates through midgut epithelium & lodges into
basal lamina → forms oocyst
○ Oocyst covered in host protein protecting it from the
immune system of the mosquito
Nuclear division occurs rapidly & center forms
Center gives rise to thousands of
SPOROZOITES
Oocyst maturation takes up to 14 days
○ Sporozoites exit oocyst, swim through hemolymph, and
attach to basal lamina of salivary glands
Then breach achieving infection
Define the oocyst.
Capsule-like structure that forms on the basal lamina of the midgut
Ookinete → oocyst
○ Undergoes sporogony to produce many sporozoites
Takes up to 14 days!
Once fully mature, sporozoites burst out and travel
to salivary glands to wait until transmission to blood
meal

○ Lecture 20
Explain the difficulties inherent in the Plasmodium life cycle that make it
difficult for us to mount an immune response.
 Immunity to malaria is complicated!
○ Antibodies can be present and still fail to protect from
malaria
○ Immunity can build over time BUT not be completely
protected
Protection not maintained in the absence of repeat
infections
○ Immunity may reduce symptom severity but not prevent
infection
○ Proteins that seem to be obvious targets fail to initiate
immune response
○ Immunity using a specific protein can be protective in some
people but not to others
Problems the Life Cycle Presents for Antigen Recognition
○ Intracellular – meaning little time outside the host cells
Sporozoite → minutes before entering liver
Merozoite → minutes before entering RBCs
○ RBCs do not express MHC
Contained within vesicle
Proteins released but not presented
○ High reproductive rate, so high variation in population
Sexual state increases variation/recombination
○ Deliberate variation in proteins
60 variants of PfEMP1 gene
Transcriptional switching
Mechanisms causing variation in surface proteins
Explain the immune response to the sporozoite
CSP coats exterior
○ Shed during transmigration through hepatocytes
○ Able to be presented via MHC1
Problems
○ Not much is presented
○ Repeat infections raise CTL response
○ Variation in CSP reduces response efficacy
Explain the immune response to the merozoite
Merozoite surface proteins can elicit antibody response
○ High degree of variation
○ Shed during infection
Problems
 ○ Antibody binding to shed protein – reduces effectiveness of
response
○ RBCs do not present antigen via MHC1
Explain the role of var gene in pfEMP1 expression and immune evasion
and response
PfEMP1
○ Expressed on surface of infected RBCs
○ 60 var genes
Only expresses one at a time
Via MHC-2
DBL (duffy binding-like) domains – in var gene
○ Variable & bind to different ligands
Ligands include molecules on surface of endothelial
cells
In blood vessels and immune molecules
Explain the role of pFEMP1 in pathogenesis
Monoallelic expression – one var gene expressed at a time
○ Controlled by epigenetic mechanisms & chromatin
modifications
○ Switching of var gene occurs