Virology

Question 1

Rabies Virus

Answer 1

• Family: Rhabdoviridae “bullet” shape enveloped, negative-sense, single-stranded RNA virus
• Genus: Lyssavirus
• Reservoir: Bats and Skunks
• Spillover into accidental hosts such as man, fox, domesticated animals…
• Rabies is a severe acute progressive encephalitis
  
  • Neurotropic virus: replicates in nerves and brain
  • No viremia (not detected in blood/serum)
  • Almost invariably fatal (Respiratory arrest)
  • Variable incubation period (2 weeks -years)
  • All mammals are susceptible
• Typically transmitted via saliva following a bite
• Travels to central nervous system (CNS) via retrograde axonal transport
• Following replication in CNS, virus travels through axons to salivary glands where it is excreted in the saliva
• Rabies Neutralizing Titer
  
  • RFFIT
  • Rapid Fluorescent Foci Inhibition Test (neutralization test)
• PRIMARY RABIES ASSAY: Direct Fluorescent Antibody Test
  
  • Rabies DFA
• Direct Detection
  
  • DFA (Primary)
  • RT-PCR
  • Direct rapid immunohistochemicaltest (DRIT)
  • Virus isolation
  • Mouse neuroblastomacell culture
  • Mouse inoculation
  • Sellers stain for Negribodies (no longer in use)
  • Real-time RT-PCR (in progress…)
• Serologic Diagnosis
  
  • IFA
  • RFFIT
• Negri bodies
  
  • Historically important, discovered by Negri in 1903.
  • Sellers stain may reveal oval inclusions in the cytoplasm of nerve cells of animals with rabies (called Negri bodies)
  • Not sensitive or specific enough for diagnostic testing
  • NOT pathognomonic for rabies!!
  • Still used in areas with no access to other methods of testing

Question 2

Rabies Law

Answer 2

California Health and Safety Code

• Laws on quarantine
• Laws on dog vaccination
• Laws on laboratory testing: “If any rabid animal, clinically suspected rabid animal or biting animal dies or has been killed, adequate specimens must be obtained and examined in a public health laboratory approved by the department
• Mandatory reporting of rabid animals to local health department immediately
• Must also report rabid livestock to CDFA
• Local animal control jurisdictions must provide annual summary of rabies activities to State Veterinary Public Health Section

Question 3

Laboratory Diagnosis In Humans Ante-mortem

Answer 3

• 1) Serum
  
  • –IFA, starting dilution is 1:4
  • –RFFIT
• 2) CSF
  
  • –IFA, starting dilution is 1:2
  • –RT-PCR
• 3) Saliva
  
  • –RT-PCR
  • –Culture in NB2A cells
• 4) Nuchal Biopsy (hair follicle from nape of neck)
  
  • look for rabies antigen in cutaneous nerves surrounding hair follicles
  • –DFA
  • –RT-PCR
• 5) Corneal Impressions no longer recommended
  
  • –DFA

Question 4

Rabies Anatomy

Answer 4

• Brain stem (BS) and Cerebellum (CB)
• Animal Brain Tissue
• Necropsy must be performed to remove the brain
• Complete cross section of brain stem is crucial for testing!!!!!
• Complete cross section of the Cerebellum (left and right lobes, and vermis)
• Optional: complete cross section Hippocampus (cerebellum is preferred)
• For bats, the whole brain is used to make slides
• Appropriate number of slides must be made from specific areas of the brain
• For larger animals (cow, horse) make slides from cerebral cortex too!
• Make tissue impression slides

Question 5

Rabies DFA

Answer 5

• Human Exposure to High Risk Animal
• Make a minimum of 4 slidesfrom cross-sections of:
• Brain Stem (BS) –ENTIRE cross-section
• Cerebellum(CB) including left and right lobes, and vermis
• AND/OR (if no cerebellum)
• Hippocampus(HP): left and right
• Make minimum of 10 slides from large animals
• Make 2 slides from bats
• Positive and Negative Control Slides
  
  • Positive brain material
  • Animals naturally infected with the most common rabies variant from the submitting area for the laboratory should be used as positive control
  • State rabies lab previously tested positive animal with CA skunk rabies variant as positive control(staining 4+/4+)
  • Negative brain material
    
    • Previously tested animal brain known to be negative
  • Storage of Control Slides
  • Slides are prepared in advance and stored at -70°C. Slides are thawed then fixed on same day as specimen is tested

Question 6

Parvoviridae

Answer 6

ss(- or +) Linear DNA with no Envelope

Slapped Cheek

Question 7

Hepadnaviridae

Answer 7

DS DNA, Linear with envelope

Question 8

Herpesviridae

Answer 8

DS DNA LINEAR with envelope

Question 9

Poxviridae

Answer 9

DS DNA linear with double envelope

Pox carriesa DNAdDNApol!

Question 10

Papillomaviridae

Answer 10

DS DNA circular no envelope

Question 11

Adenoviridae

Answer 11

DS DNA Linear with no envelope

Question 12

TORCH

Answer 12

• Pneumonic for pathogens that cross the placenta and may affect the developing fetus
• Toxoplasma gondii
• Other –Syphilis, Listeria, Brucella, Zika, ParvoB19
• Rubella
• CMV
• HSV

Question 13

RNA Viruses–Key Concepts

Answer 13

• RNA genomes may be single- or double-stranded (ss or ds);
• haploid (1), diploid (2); linear, circular, segmented
• ss (+)sense RNA genomes are translation-competent upon release, i.e., essentially they are like mRNA
• ss (–)RNA is “anti-sense”, meaning it needs to be transcribed by a viral polymerase to mRNA before viral proteins can be made
• All RNA viruses encode a viral polymerase
• In (-)sense RNA viruses, this polymerase is carried in the virus, ready to be used when the virus infects a cell (“Virion-associated”)
• Diploid ss (+)sense RNA viruses (Retroviruses) are special.
  
  • They are the only RNA viruses known to go through a DNA phase in their replication cycle

Question 14

Picornaviridae

Answer 14

• • sense ssRNA
• Enterovirus (15)
• Hepatovirus(9)
• Polio, enteros,rhinos HepatovirusA (HAV)
• No envelope
• Rash, encephalitis, Hepatitis
• Fecal-oral(polio, HAV), fomites, and/or respiratory (enteros, rhinos)
• Hepatovirus: Hepatitis A virus
• Cardiovirus: Encephalo-myocarditis virus
• Kobuvirus
• Cosavirus
• Apthovirus: Foot-and-mouth disease virus
• Teschovirus

Question 15

Togaviridae

Answer 15

• Toga, meaning thick envelope
• (+) ssRNA, 50-60nm enveloped icosahedrons, 2 glycoproteins
• Genus Alphavirus:
• A large genus of mosquito-borne viruses
• 32 species, transmitted by mosquitoes
• E.g., Chikungunya, WEE, EEE, VEE*
• All medically important alphaviruses are arthropod-borne (e.g. mosquito vectors) and have non-human hosts
• Humans tend to be “dead-end” hosts (don’t transmit to others): Except CHIK

Question 16

Retroviridae

Answer 16

• diploid (+) ssRNA(2 copies)
• HTLV and HIV
• “Reverse Transcriptase”:
• ssRNA dsDNA via virus-encoded RNA-dependent DNA polymerase (RdDp)
• Enveloped, SS, diploid, + sense, RNA
• Integration of Viral Genome into Host DNA
  as a Provirus
• Latency
• Oncogenic and Cytopathic varieties

Question 17

(-) ssRNAViruses

Answer 17

• All are enveloped viruses
• These viruses also must carry an RNA-dependent RNA polymerase (RdRp) in order to make positive sense of mRNA
• Paramyxo
  
  • Measles, Mumps
  • Syncytia, also known as multinucleated giant cells, visible by staining
• Orthomyxo- InfluenzaA (H1N1)
  
  • Influenza B
  • Bourbon
• Filo-Zaire Ebolavirus
• Marburg
• Rhabdo-Rabies
• Hanta-SinNombre

Question 18

Reoviridae

Answer 18

• dsRNA Respiratory Enteric Orphan viruses
• No envelopes
• Triple layered: outer & intermediate layers and an inner core
• 11 segments dsRNA
• Carries RNAdepRNApol

Question 19

Order Rickettsiales

Answer 19

• Small obligate intracellular bacteria
• 0.3 to 0.5 um by 1 to 2 um
• Gram-negative cell wall structure
• Poorly staining
• Rickettsiagroup specific LPS; Orientialacks LPS
• A+T-rich genome
• Lack genes for sugar metabolism, lipid biosynthesis, nucleotide synthesis, and amino acid synthesis

Question 20

Rickettsiales: Common Features

Answer 20

• Arthropod Vectors: ticks, fleas, mites, or lice
• Geographic distribution is determined by vector
• Most are Zoonoses
• Don’t survive outside living host for long (R. prowazekii exception)
• Similar disease syndrome that may differ in severity
• Fever, Headache, Eschar (dark, scabbed plaque overlying a shallow ulcer), Rash(vasculitis)
• “Undifferentiated febrile illness”
• Lab Values: Thrombocytopenia, Elevated Hepatic Transaminases, Hyponatremia
• Susceptible to tetracycline/doxycycline
• Prevention through vector control and sanitation measures

Question 21

Rickettsia Detection

Answer 21

• Microscopy
  
  • Gimenezor Wright-Giemsa stain of blood smears and buffy coat
  • Morulae in cytoplasm of Ehrlichia-and Anaplasma-infected leukocytes
• Culture
  
  • Cannot be isolated by standard blood culture
  • Grow in cell culture (Vero E6)
  • R. rickettsiiis a biosafety level 3 agent(high rate of laboratory-acquired infections)
• Immunohistochemistry
  
  • CDC
• Nucleic Acid Amplification
  
  • Specimen Types
    
    • Whole blood: best for Ehrlichiaand Anaplasma
    • Tissue (eschar, skin biopsy, CSF) best for SFG Rickettsia
  • Antibiotic treatment decreases PCR sensitivity
  • Species-level identification possible
• Serologic Detection
  
  • Indirect Immunofluorescence Antibody Assay (IFA)
    
    • Group-level Identification (TG vs. SFG)
    • Four-fold rise in titer is diagnostic
    • Highly sensitive 2-3 weeks after onset; insensitive during 1stweek (Effective anti rickettsial treatment of RMSF must be initiated within 5 days of onset)
    • Weil-Felix Test (historical)
      
      • Agglutination through cross-reaction with P. vulgaris somatic antigens

Question 22

Rickettsia by Disease

Answer 22

• Typhus Group
  
  • Epidemic Typhus
  • Murine Typhus
• Scrub Typhus
• Spotted Fever Group
  
  • RMSF
  • MaculatumInfection
  • Pacific Coast Tick Fever
  • Rickettsialpox
• Anaplasmosis and Ehrlichiosis

Question 23

Epidemic Typhus

Answer 23

• Agent: R. prowazekii (pronounced “prowachecki”)
  
  • Select Agent: weaponized and antibiotic resistant strains developed
• Transmission
• Reservoir: Humans; Glaucomysvolans (Southern Flying Squirrel)
• Vector: Pediculus humans corporis (louse) (Infects midgut)
• Epidemiology
  
  • Worldwide: associated with unsanitary, crowded conditions
    
    • 3 million deaths during WWI
    • Large outbreaks in refugee camps
  • Sylvatic Typhus: Contact with flying squirrel nests (fecal dust inhalation?)
  • Distribution: Eastern states
• Signs/Symptoms
  
  • IP: 7-14 days
  • ILI, N/V, cough, maculopapular rash, confusion
  • Brill-Zinsser: subclinical persistence; relapse months to years after first onset
  • Case-fatality Rate: 10-30% if untreated

Question 24

Murine Typhus (Endemic)

Answer 24

• Agent: R. typhi
• Transmission
  
  • Reservoir: Rats, Cats, Opossum
  • Vector: Xenopsyllacheopis(Rat flea), Ctenocephalidesfelis(Cat flea), Leptopsylliasegnis(Mouse flea)
• Epidemiology
  
  • Worldwide: tropical and subtropical climates
  • United States: California (Los Angeles, Orange counties), Hawaii, Texas
• Signs/Symptoms
  
  • IP: 7-14 days
  • ILI, N/V, cough, maculopapularrash

Question 25

Scrub Typhus

Answer 25

• Agent: Orientiatsutsugamushi
• Transmission
  
  • Reservoir: Rodents
  • Vector: Infected chiggers (larval thrombiculidmites)
• Epidemiology
  
  • “World’s most important Rickettsialinfection in terms of disease burden” –nearly 1 million cases per year
  • Southeast Asia, Indonesia, China, Japan, India, Northern Australia
    
    • Rural areas with mite-harboring vegetation
• Signs/Symptoms
  
  • IP: 7-10 days
  • ILI, Eschar, Mental Changes, Enlarged Lymph Nodes, MaculopapularRash (25-50% of cases)

Question 26

Rocky Mountain Spotted Fever (RMSF)

Answer 26

• Agent: R. rickettsii
  
  • Infects vascular endothelial cells
  • BSL-3 level pathogen
• Transmission:
  
  • Reservoir: Rodents, Dogs,
  • Ticks (transovarial)
• Vector:
  
  • Dermacentorvariabilis(American dog tick); eastern US, central US, and pacific coast
  • D. andersoni(Rocky Mountain wood tick); western US
  • Rhipicephalus sanguineus(brown dog tick); Arizona
  • Spent 95% of life hidden in cracks/crevices of human habitations
• Epidemiology
  
  • Incidence: 8.9 cases per million
  • Arizona Indian reservations: 1,360 cases per million
  • Arkansas, Missouri, North Carolina, Oklahoma, and Tennessee account for 63% of cases
  • Baja California: 4,300 cases from 2009-2019
  • Hyperendemicity linked to an overabundance of tick-infected, free-ranging dogs
• Signs/Symptoms
  
  • Incubation Period: 3-12 days
  • Fever, ILI, spotted or generalized maculopapular rash (palms and soles)2 to 4 days after fever, GI involvement; rare inoculation eschar
  • Late stage manifestations: meningoencephalitis, acute renal failure, ARDS, shock
  • 5-10% case-fatality rate
• The majority of broad spectrum antibiotics are not effective against Rickettsia, Ehrlichia, or Anaplasma

Question 27

Rickettsialpox

Answer 27

• Agent: R. akari
• Infects macrophages
• Transmission
  
  • Reservoir: House mice, wild rodents
  • Vector: Mite
• Epidemiology
  
  • Distribution: Former Soviet Union, South Africa, Korea, Turkey, Balkan region, USA (New York –5 cases annually)
• Signs/Symptoms
  
  • IP: 10-14 days
  • ILI, eschar, vesicular rash, thrombocytopenia
  • Chickenpox differential dx

Question 28

Anaplasmosis (Human Granulocytic Anaplasmosis)

Answer 28

• Agent: Anaplasma phagocytophilum
  
  • Infects granulocytes
• Transmission
  
  • Reservoir: Small mammals, rodents, deer, dogs
  • Vector: I. scapularis, I. pacificus
• Epidemiology
  
  • Incidence: 6.3 cases per million
  • US Distribution: Northeast and upper Midwest
  • CA Reportable Condition: 5 cases per year
• Signs/Symptoms
  
  • IP: 5-14 days
  • Systemic inflammatory response; Leukopenia
  • ILI, rash (rare), severe clinical course possible
  • Co-infections with Borrelia, Babesia, Powassanvirus
  • Case-fatality rate < 1%

Question 29

Ehrlichiosis (Human MonocyticEhrlichiosis)

Answer 29

• Agent: Ehrlichia chaffeensis
  
  • Infects monocytes and tissue macrophages
• Transmission
  
  • Reservoir: Deer, rodents, dogs
  • Vector: Amblyommaamericanum(Lone Star Tick)
• Epidemiology
  
  • Incidence: 3.2 cases per million
  • US Distribution: Southeast esp. Arkansas, Missouri, Oklahoma, Tennessee, and Virginia
  • CA Reportable Condition: 1 case per year
• Signs/Symptoms
  
  • IP: 5-14 days
  • Leukopenia
  • ILI, GI and Neurologic manifestations, variable pattern Rash (adults = 30%, children = 60%), cough/respiratory symptoms, meningoencephalitis
  • Case-fatality rate: 3%

Question 30

Query (Q) Fever

Answer 30

• Agent: Coxiella burnetii
  
  • Obligate Intracellular Bacteria
  • Anexic(cell-free) culture possible
  • Gammaproteobacterium, Legionellales, Coxiellaceae, Coxiella
  • Select Agent (BSL3)
• Transmission:
  
  • Reservoir: Domestic Livestock
  • Vector: None
  • Inhalation of aerosols from urine, feces, amniotic fluid, and placental tissue; unpasteurized dairy products
  • Infectious dose: 1 spore
• Epidemiology:
  
  • Occupational disease: Farmers, Vets, Abattoir workers
  • Worldwide distribution; Geocentric: California, Texas, Colorado, Illinois
  • Seroprevalence= 3.1%
  • Netherlands OB: 4,000 cases associated with goat dairy farms
• Pathogenesis:
  
  • Infects alveolar macrophages
  • Prevents phagolysosome fusion and activation of apoptosis by high jacking host cell signaling pathways
• Signs/Symptoms:
  
  • IP: 2-3 weeks
  • ILI, prolonged high fever (105°F), pneumonia, hepatitis, rare rash
  • Chronic Form: relapse months to years after onset; endocarditis
• Laboratory:
  
  • Select Agent!
  • Serology (IFA), PCR, IHC, Cell culture
  • Acute Infection: antibodies to phase II antigens(avirulent, high passage form) predominate
  • Chronic Infection: antibodies to phase I antigens(virulent form) predominate
• Treatment: Doxycycline for 2 weeks (acute) or several months (chronic)

Question 31

Zika Virus

Answer 31

• General
  
  • 1st isolated from a sentinel Rhesus macaque –Zika Forest in Uganda in 1947
  • Zika virus is a mosquito-borne flavivirus similar to dengue, yellow fever, West Nile, and Japanese encephalitis viruses
  • Like dengue and chikungunya, Zika isolated from Aedes mosquitoes
• Zika virus Infections
  
  • Generally, mild febrile rash illness lasting 2-7 days
  • 4/5 people infected are asymptomatic
  • Symptoms most commonly reported:
    
    • Fever
    • Maculopapular skin rash
    • Conjunctivitis
    • Muscle and joint pain
    • Malaise
    • Headache
  • Rarely severe or fatal illness
• Zika Microcephaly
• Definition: Head circumference at birth >2 standard
  deviations below the mean for gestational age and sex
• Outcomes:
  
  • Range from normal to severe, including death
  • Can include seizures, visual or hearing deficits
  • Correlate with severity of microcephaly
• Causes:
  
  • Congenital infection: e.g. syphilis, rubella, toxoplasmosis
  • Genetic disorders and inherited mutations
  • Other brain injuries: hypoxia, drugs, toxins, FAS
  • Epidemiology:
    
    • 2‐12/10,000 live births in US
• Guillain‐BarréSyndrome (GBS)
  
  • Autoimmune neurologic disease causing weakness and/or paralysis
  • Outcomes:
  • Respiratory weakness needing ventilatory support in 10‐30%
  • Autonomic dysfunction in 70%; can lead to sudden death

Question 32

Zika Virus Detection

Answer 32

• Zika viremia is low and of short duration
• Viral loads <3.5 X 103 viral particles/ml compared to ~107–108 for dengue and chikungunya (Lanciotti et al., 2008)
• The virus is often no longer detectable in serum at or shortly after symptom onset
• Most detections of Zika virus by RT-PCR in serum: <3 days of illness onset
• Zika-specific IgM can appear later in course of infection
• Samples collected <7 days after onset can be falsely negative
• Zika virus IgM may persist as long as dengue virus IgM (~12 weeks) –little data
• Flavivirus-specific antibodies (IgM & IgG) cross-react requiring confirmation
• No good tests available to diagnose acute Zika virus disease
• Prolonged ZIKVIgM may make it difficult to determine timing of infection
• RT-PCR
  
  • Sensitivity:
  • Serum = 51%
  • Urine = 90.62%
  • Specificity of urine or serum PCR = 100%

Question 33

Ebola virus disease (EVD)

Answer 33

• Filoviridae
  
  • 8 genera
  • Enveloped virus
  • 19 kb linear ssRNA
  • RNA dependent RNA polymerase
  • Marburg (1967) and Ebola (1976)
• Ebola virus Genus
  
  • 6 Species
    
    • Zaire ebolavirus = Ebola virus
    • Sudan ebolavirus = Sudan virus
    • Bombali ebolavirus
    • Bundibugyo ebolavirus
    • Taï Forest ebolavirus
    • Reston ebolavirus (causes monkey death and swine infection, not human; originated in the Philippines)
  • Zaire, Bundibugyo, and Sudan ebolaviruses have all caused large outbreaks in Africa

Question 34

*Ebolavirus Disease (EVD)
Epidemiology*

Answer 34

• First recognized in 1976
• One of 2 outbreaks that year occurred in a village near the Ebola River, hence its name
• Equatorial Africa
• Natural reservoir Pteropodidae fruit bats
• Able to infect humans, monkeys, chimpanzees, gorillas, baboons, and duikers; serologic evidence in domesticated dogs
• Spread through contact with infected animals, including human to human

Question 35

EVD Transmission Routes

Answer 35

• Zoonotic : Handling sick dead primates and fruit bats, including bushmeat
• Human: Exposure to blood body fluids
• Human to Human transmission causes
  epidemics
• Not an airborne pathogen

Question 36

Ebola Pathogenesis

Answer 36

• Infectious Dose = 1-10 virus particles
• Portal of entry: mucous membranes, breaks
  in the skin, or parenterally
• Migrates from the initial infection site to
  regional lymph nodes and subsequently to
  the liver, spleen, and adrenal gland
• Causes immune system dysregulation and
  cytokine storm
• Disrupts cell adhesion molecules, leading to cell death, vascular, instability, and shock
• A rare, often fatal, viral hemorrhagic fever

Question 37

LRN U.S. Ebola tests

Answer 37

• FDA EUA real time RT PCR assays
  
  • RNA ~detectable 3 10 days after symptom onset
  • RNA is extracted following Trizol inactivation
  • 2 CDC LRN Ebola Zaire RT qPCR assays (VP40 and NP):
  • Whole blood, serum, plasma, urine
  • EBOV testing requires prior approval from CDC
• CDC only:
  
  • Virus isolation
  • Serologic testing for IgM & IgG
  • Tests for other pathogens

Question 38

EBOV is a Select Agent

Answer 38

• Extreme biohazard risk.
  
  • Culturing specimens from Ebola PUIs must be done in a BSL4 (CDC)
  • Handling specimens from suspected case may be done in BSL2 (Hospital or PHL)
  • Recommended: Handle all original samples in BSL3 until inactivated
  • A positive PCR result alone is not cause for select agent classification; EBOV nucleic acid does not fall under SA rules
  • Specimens from a suspected Ebola patient are not covered by the Select Agent regulations, unless EBOV has been cultured from that patient
  • Positive Ebola culture at CDC? Then all specimens from that patient fall under Select Agent rules
• Avoid/minimize aerosol generating
  procedures
• PPE: Coveralls with feet; Front closing
  gown; Double gloves; PAPR

Question 39

EBV treatment

Answer 39

• Strict Isolation from other patients
• Supportive care rehydration improves survival
• Treating other infections if they occur
• Remdesivir, a viral polymerase inhibitor and one of the drugs used to treat COVID, was less effective than the mAb treatments
• Favipiravir, another pol inhibitor, may have cleared the virus from 2 male long term survivors (from detectable to undetectable by PCR in semen)
• Survivors: detectable levels of antibodies for 10 years
• rVSV ZEBOV Vaccine: Ervebo
  
  • Live, attenuated recombinant vesicular stomatitis virus vaccine approved for use in adults (2019)

Question 40

West Nile Virus (WNV) General Characteristics

Answer 40

• Arboviruses
• ARthropod-BOrneVIRUSes
• Flaviviridae
  
  • Zika
  • St Louis encephalitis (SLE)
  • Dengue
  • TBE, Powassan
• Characteristics
  
  • Spherical, enveloped
  • Single-stranded, positive sense, non-segmented RNA
  • First identified in Uganda, 1937
• The “West Nile fever” syndrome can differ among individuals
• IP: 2 to 15 days
• Common symptoms:
  
  • Fever
  • Headache
  • Muscle pain or weakness
  • Fatigue
  • Other less common symptoms include rash, swollen lymph nodes, nausea, vomiting, eye pain
  • Encephalitis
  • 60-75% of WNV cases are encephalitis or meningoencephalitis Meningitis
  • 25-35% of WNV cases are meningitis only
  • Acute flaccid paralysis (AFP, AFM)
  • Adult acute onset of asymmetric weakness in the absence of sensory loss
  • Less common than meningitis or encephalitis

Question 41

West Nile Virus (WNV) Transmission

Answer 41

• MOSQUITO-CULEX
• Blood transfusion
• Organ transplant
• Anecdotal evidence of transplacental and breast milk transmission
• Birds are primary amplifier hosts
  
  • Migratory birds can expand endemic region
  • WNV isolated from numerous wild birds
  • >200 bird species affected
  • Ranges from no clinical signs in some species to over 90% fatality in others

Question 42

*West Nile Virus
Laboratory Diagnosis*

Answer 42

• Unexplained encephalitis or meningitis
• Onset during WNV “season”
• Location of exposure
  
  • In CA: local activity
  • Travel outside of CA: consider non-endemic arboviruses
• Confirmed:
  
  • Isolation of virus from, or demonstration of specific viral antigen or nucleic acid in, tissue, CSF, blood, or other body fluid
  • Four-fold or greater change in virus-specific quantitative antibody titers in paired sera,
  • Virus-specific immunoglobulin M (IgM) antibodies in serum with confirmatory virus-specific neutralizing antibodies in the same or a later specimen
  • Virus-specific IgM antibodies in CSF and a negative result for other IgM antibodies in CSF for arboviruses endemic to the region where exposure occurred.
  • Probable:
    
    • Virus-specific IgM antibodies in serum
• IgM EIA and IFA
• IgG IFA
  
  • Paired specimens only
• Plaque reduction neutralization test (PRNT)*
• WNV nAbtiter ≥4x SLEV nAbtiter
• PCR
  
  • CSF only
• Neutralization​
  
  • Loss of viral infectivity through the reaction of virus with neutralizing antibody
  • Highly specific*
• Neutralization Functional assay
  
  • Cell culture system with infectious virus
  • Measure neutralizing antibody in patient serum/CSF
    
    • MMR, YF, RFFIT, SC2
  • ID specific arbo
    
    • WNV vs SLE
    • Zika vs DENV

Question 43

West Nile Virus (WNV) Vectors

Answer 43

• Aedes aegypti
  
  • “yellow fever mosquito”
  • Aggressive, day biting
  • Introduced 2013
  • DENV, CHIKV, ZIKA, YF (WNV)
• Aedes albopictus
  
  • “Asian tiger mosquito”
  • Aggressive, day biting
  • Introduced 2011
  • DENV, CHIKV (ZIKA, YF, WNV)

Question 44

Yellow Fever

Answer 44

• Flavivirus
  
  • Many historical outbreaks
  • 1793, Philadelphia, PA: ~5000 deaths (10% pop.)
  • 1853, New Orleans, LA: 7,849 deaths, delayed alerts
• Vaccine-preventable
  
  • Max Theiler, 1951 Nobel Prize
• Human and other primate reservoirs
• Vectorborne
  
  • Aedes spp.
• Clinical syndromes
  
  • Mild: Fever, headache, jaundice, nausea, vomiting, backache.
  • Severe: High fever, jaundice, bleeding, shock, organ failure, 30-60% fatality in severe case-patients.
• Testing:
  
  • Acute infection: RT-PCR, paired IgG, IgM + PRNT (CDC)
  • Immunity: PRNT (CDC)
  • Immunocompromised, vaccine failures
  • Vaccination history and detailed travel history (and more) required

Question 45

JEV( Japanese Enchapilitis Virus)

Answer 45

• Flavivirus
• Vectorborne
  
  • Culex spp.
• Animal reservoirs (primarily pigs and wading birds)
  
  • SE Asia, mostly rural
• Vaccine-preventable
• Ranges from asymptomatic to severe CNS, encephalitis

Question 46

Dengue Fever Virus

Answer 46

• Flavivirus
  
  • DENV-1, DENV-2, DENV-3, DENV-4 viruses
• Homotypic (type-specific) immunity
• Human and other primate reservoirs
• Vectorborne, bloodborne, maternal transmission
• Asymptomatic, dengue, severe dengue
• RT-PCR (including DENV-1-4), IgM + PRNT
• Case definition similar to WNV
• Symptomatic pregnant women tested for both Zika and DENV
• Confirmatory ZIKV-DENV PRNT
• Title 17 CCR §2505 laboratory reportable condition
• Symptoms
  
  • ~80% asymptomatic
  • Dengue (dengue fever, break-bone fever)
    
    • Nausea/vomiting, rash, myalgia/arthralgia, tourniquet test positive, leukopenia
  • Severe dengue (DHF, Dengue shock syndrome)
    
    • Severe plasma leakage leading to shock or fluid accumulation with respiratory distress; severe bleeding; or severe organ impairment
    • Increased risk of severe dengue in persons with previous dengue infections. May be associated with antibody-dependent enhancement at low, non-neutralizing Ab titers.

Question 47

Chikungunya Virus

Answer 47

• Togaviridae> Alphavirus
  
  • 1952, Tanzania
• Makonde: “that which bends up”
• Dec 2013, Western hemisphere
• Human and other primate reservoirs
• Vectorborne
• Mostly symptomatic: fever, arthralgia
• RT-PCR, IgM + PRNT
  
  • Case definition same as WNV
  • Confirmatory CHIKV-WEE PRNT
  • Title 17 CCR §2505 laboratory reportable condition

Question 48

Zika Virus

Answer 48

• Flavivirus
• Human and other primate reservoirs
• Vectorborne, bloodborne, maternal, and sexual transmission
  
  • Asx, sx, congenital neuro abnormalities, GBS
• Nucleic acid testing (NAT), IgM + PRNT
  
  • Case definition includes any detection of Zika nAb
• Title 17 CCR §2505 laboratory reportable condition​
• Symptoms
  
  • ~80% asymptomatic
  • Mostly mild febrile illness
  • Rash
  • Arthralgia
  • Fever
  • Conjunctivitis
  • Congenital abnormalities
  • CZS, IUGR, neurologic sequelae in children and adults
  • Highest risk from infection in 1sttrimester
  • Congenital Zika Syndrome (CZS)
    
    • Severe microcephaly where the skull has partially collapsed
    • Decreased brain tissue with a specific pattern of brain damage
    • Damage (i.e., scarring, pigment changes) to the back of the eye
    • Joints with limited range of motion, such as clubfoot
    • Too much muscle tone restricting body movement soon after birth
• Guillain-Barrésyndrome (GBS)
  
  • Rare, temporary post-infectious autoimmune disorder
  • Muscle weakness, paralysis lasting weeks to months

Question 49

*St. Louis Encephalitis Virus (SLEV)
General Background*

Answer 49

• Flavivirus
  
  • closely related to WNV
• Culex vector
• Bird amplifier reservoir
• Fresno and Tulare, CA, 1937: first detections in CA (nAb-neutralizing antibody)
• Clinically similar to WNV
• Asx→ CNS disease
• No vaccine, supportive care only
• VRDL:
  
  • IgM EIA*
  • IgM and IgG IFA (serum only)
  • RT-PCR*
  • PRNT*

Question 50

(PRNT) Assay

Answer 50

• Plaque Reduction Neutralization Tests
• The CDC requires that samples with presumptive positive, equivocal, or inconclusive IgM test results for the Zika virus must be forwarded for confirmation by PRNT.
• The PRNT is a serological test that utilizes the ability of a specific antibody to neutralize a virus, in turn, preventing the virus from causing the formation of plaques in a cell monolayer.

Question 51

Neutralization: Definition

Answer 51

• Loss of viral infectivity through the reaction of virus with neutralizing antibody
• Neutralization assay is highly specific
• Serotype: sera specific for a given serotype does not neutralize other serotypes
• Three Components
  
  • Virus: known or unknown
  • Serum: known or unknown
  • Host system(cell cultures)
• Prepare a series of dilutions (usually 10 fold) of viral prep and inoculate the appropriate host system
• Score for viral growth:
  
  • Quantal: CPE
  • Quantitative: plaques
• Titer: Quantitative
  
  • Reciprocal of highest dilution with countable plaques times the number of plaques
  • Example 50 plaques at the 1:1,000 dilution, titer is 5 X 104PFU/unit
• Titer: Quantal
  
  • Titer is the reciprocal of dilution giving 50% endpoint—1 TCID50
• Reciprocal of the dilution at the 50% endpoint of measurable effect (CPE)
• Neutralization test: aim for 100 TCID50
  
  • acceptable range 32 -320 TCID50
  • Titerate virus as part of neutralization test
  • Serial 10-fold or .5 log dilutions of virus
  • Mix viral dilutions with equal volume of diluent (maintenance media for cell culture)
• Possible mechanisms
  
  • Antibody blocks virus attachment to host cell
    
    • bind to virus
    • bind to host cell
  • Antibody stabilizes viral capsid so that nucleic acid cannot uncoat
  • Form viral aggregates

Question 52

Enterovirus-Genus

Answer 52

• Single, Positive Stranded RNA
• 7,200—7,600 bases long
• Enterovirus: replicate in gastro-intestinal tract, upper respiratory tract, brain and other major organs; acid-stable
• Rhinovirus: replicate in the upper and lower respiratory tract; acid-labile
• Detection of HEV and HRV
  
  • Viral culture: CPE confirmed by type-specific monoclonal ab(HEV) or neutralization
  • Direct detection:
    
    • DFA
    • RT-PCR
  • Serology:
    
    • IgM Detection

Question 53

Measles

Answer 53

• Paramyxoviridae (Genus Morbillivirus)
• (-) ssRNA
• Transmitted by respiratory droplets & fomites
• May cause severe or fatal disease
• Humans are only known hosts
• Only 1 recognized serotype each
• 1 serotype, 24 genotypes
• Incubation period: 10-12 days
• Prodrome lasts 2-4d (range 1-7d)
• High fever (to 104F/40C)
• The 3 Cs: Cough, coryza, conjunctivitis
• May have Koplik spots (rash on mucous membranes of mouth)
• Rash
  
  • Begins on face and head (forehead and the ears), moves downward, becoming confluent in 24-36 hours
  • Maculopapular
  • bumpy/not vesicular and not itchy
  • Bumps vary in size from 0.1 to 1.0 cm and vary in color from dark red to a purplish hue
• Treatment is supportive. No antiviral.
• Measles is highly contagious: a single case may result in another 15-17 cases in a naïve population (R0 )
  
  • Transmission: droplet/aerosol
  • Aerosolized virus viable 30+ minutes
  • Transmission can occur for up to 2 hours after an infectious person has left an exposure setting
  • Cases are infectious from 4 days prior to 4 days after rash onset
• Testing
  
  • NP or throat swab in VTM
    
    • 0-7d after rash onset
    • RT-PCR, genotyping
  • Urine
    
    • 0-10 after rash onset
    • RT-PCR, genotyping
  • Serum
    
    • Acute (3-14d)
    • LDT EIA/IFA for IgM/IgG

Question 54

Rubella

Answer 54

• Matonaviridae (Genus Rubivirus)
• (+) ssRNA
• enveloped virus
• Fragile virus: easily destroyed by heat, detergent, and pH extremes
• Transmitted by respiratory droplets & fomites
• May cause severe or fatal disease
• Humans are only known hosts
• Only 1 recognized serotype each
• Clinically similar to measles, but fever tends to be lower and rash is fainter
• 20-50% subclinical disease
• Illness typically mild in children: Fever, inflamed lymph nodes, sore throat, mild cough, and pink rash of discrete spots that may desquamate
• More severe in adults (polyarthralgias)
• Complications: Post-infectious encephalopathy (1/6000), bleeding disorders due to thrombocytopenia (1/3000)
• Spread by respiratory droplet+7d from rash onset; less infectious than measles & requires close contact
• Spreads transplacentally**
  
  • Rubella infection in pregnancy can cause miscarriage, stillbirth, & congenital anomalies
  • Cataracts, heart defects, hearing loss, and microcephaly​
• ​Vaccine
  
  • Highly effective vaccine that is well tolerated in children
  • 1 dose: ~97% Efficacy
  • Confers life-long immunity
  • 1983 study: 10% US women lacked detectable Ab titers, but they responded rapidly when challenged with high titered virus
• Diagnosis
  
  • RT-qPCR
    
    • In PCR positive patients with both respiratory and urine samples, Ct values have been higher in urine (eg, less RNA)
    • Urine an effective sample in cases of CRS
    • Positive samples are genotyped
  • IgM
    
    • False positives: pregnant women; parvovirus B19 infections; Rheumatoid factor; heterophile Ab
  • IgG: Testing acute/convalescent paired sera useful for confirming IgM specificity
  • NP or throat swab in VTM
    
    • 1-10d after rash onset
    • RT-PCR, culture, genotyping
  • Urine (infants only?)
    
    • 4d after rash onset
    • culture
  • Serum
    
    • Acute (2-14d)
    • IgM & IgG

Question 55

Varicella Zoster

Answer 55

• Herpesviridae (Alphaherpesvirinae)
• dsDNA
• Transmitted by respiratory droplets & fomites
• May cause severe or fatal disease
• Humans are only known hosts
• Only 1 recognized serotype each
• Large, enveloped virus
• Virus establishes latency in 1-7% of sensory ganglia neurons
• During dormancy, there are 2 to 9 non-infectious, circular genome copies in each affected neuron
• Reactivation: Shingles (Zoster)
• Incubation period (time to disease)14 to 16 days (range 10 to 21 days)
• VZV replicates in the respiratory cells and regional lymph nodes
  4-6 days after infection, a primary viremia (virus in the blood) occurs, disseminating virus to other organs -liver, spleen, and sensory ganglia
• Further replication occurs in the viscera, followed by a secondary viremia, with viral infection of the skin, leading to characteristic rash
• Antivirals –1̊Acyclovir and related drugs w/in 24 hr

Question 56

Mumps

Answer 56

• Paramyxoviridae (Genus Rubulavirus)
• (-) ssRNA
• Transmitted by respiratory droplets & fomites
• May cause severe or fatal disease
• Humans are only known hosts
• Only 1 recognized serotype each
• Stable for several days at 4C
• Transmitted by airborne droplets, fomites
• Long incubation: 16-25 d
• Symptoms typically mild & self-limiting
• Fever, headache, lethargy
• 90% have painful unilateral/bilateral swelling of parotid (salivary) glands
• 30% sub-clinical (asymptomatic)
• IFA: IgM & IgG
• Not ideal: Nonspecific (false positive) reactions may occur (AV, EBV, HHV6, PIV, others?)
• RT-PCR of buccal swab is test of choice
• Need 30s massage of parotid/salivary gland
• Narrow collection window: 1-3d after parotitis onset
• PCR(+) samples are genotyped

Question 57

Hepatitis A Virus

Answer 57

• Family: Picornaviridae, Genus: Hepatovirus
• + ssRNA, slow-growing, no cytopathic effect
• Infects hepatocytes; unknown cell receptor
• Quasi-enveloped
• Serum/Plasma: host-derived envelope, immune evasion
• Feces: naked virus, environmentally stable
• Single serotype
• Three genotypes cause human illness
  
  • Subtype IA: >80% of US strains
  • Subtype IB: 16% of US strains
  • Subtype IIIA: rare in US, 5 detected by CDC in last 10 years
  • Subtypes IIA, IIB, and IIIB: very rare
• Acceptable Specimens
  
  • Serum and Plasma
  • IgM positive, symptomatic patient or person exposed to a known case or risk factor for HAV
• Test Menu
  
  • rRT-PCR for HAV identification (genus/species)
  • Triplex rRT-PCR for HAV subgenotypeidentification (type/subtype)
  • Nested RT-PCR for SubgenomicSanger Sequencing (genotype/strain)
  • Whole Genome Sequencing (genotype/strain)
• ​Only vaccine-preventable foodborne disease in the U.S.
• Two primary food groups have been linked to HAV outbreaks
  
  • Produce –berries, green onions, lettuce
  • Seafood –oysters, clams, mussels

Question 58

Hepatitis E Virus

Answer 58

• It was previously classified in the Caliciviridae family.
• However, its genome more closely resembles the rubella virus.
• It is now classified as a member of the genus Hepevirus in the Hepeviridae family.
• Single-stranded positive-sense RNA virus
• Genus Hepevirus
• Family Hepeviridae
• Four genotypes
• Enterically Transmitted: water-borne and recently discovered zoonotic transmission.
• Incubation period: Average 40 days with a Range 15-60 days
• Case-fatality rate:
  
  • Overall, 1%-3%
  • Pregnant women, 15%-25%
• Developing countries: epidemics associated with fecally contaminated drinking water
• Minimal person-to-person transmission
• Developed countries: travel-associated and autochthonous (zoonoses from undercooked pork and wild game).
• Vaccine: Currently available in China only
  *

Question 59

Hepatitis B Virus

Answer 59

• Hepatitis B virus (HBV) is a partially double-stranded DNA virus
• Hepadnaviridae family of viruses (genus Orthohepadnavirus)
• High
  
  • blood
  • serum
  • wound exudates
• Moderate
  
  • semen
  • vaginal fluid
  • saliva
• Low/Not Detectable
  
  • urine
  • feces
  • sweat
  • tears
• HBV Perinatal Transmission
  
  • Transmission most likely during birth
  • In absence of immunoprophylaxis: overall transmission rate of 5-90%
  • MotherHBeAg-, (<10%) HBeAg+ (70-90%)
• ​Incubation period (days):
  
  • Average 60-90
  • Range 45-180
• Chronic infection:
  
  • <5 yrs, 30%-90%!!
  • ≥5 yrs, 2%-10%
• HBV Markers
  
  • Anti HBs antibodies
    
    • Immunity
  • Anti HBc antibodies
    
    • Exposure
  • HBs Ag and/or HBV DNA
    
    • Infection
  • HBe Ag and/or HBV DNA
    
    • Replication
  • IgM anti HBc and/or HBV DNA
    
    • Disease
• Vaccine
  
  • Prevent perinatal HBV transmission
  • Routine vaccination of all infants
  • Vaccination of children in high-risk groups
  • Vaccination of adolescents
    
    • all unvaccinated children at 11-12 years of age
    • “high-risk” adolescents at all ages
  • Vaccination of adults in high-risk groups

Question 60

Hepatitis D (Delta) Virus

Answer 60

• ss RNA Virus
• Defective virus -requires the presence of Hepatitis B Virus to replicate.
• Uses the Hepatitis B Surface Antigen as an envelope
• Percutaneous exposures
  
  • injecting drug use
• Permucosal exposures
  
  • sex contact
• Coinfection
  
  • severe acute disease
  • low risk of chronic infection
• Superinfection
  
  • usually develop chronic HDV infection
  • high risk of severe chronic liver disease

Question 61

Hepatitis C Virus (HCV)

Answer 61

• enveloped
• positive-sense single-stranded RNA
• family Flaviviridae
• genus Hepacivirus
• 7 genotypes, 60 subtypes
• High nucleic acid variability
• Incubation period:
  
  • Average 6-7 wks
  • Range 2-26 wks
• Clinical illness (jaundice):
  
  • 30-40% (20-30%)
• Chronic hepatitis:
  
  • 70%
• Immunity:
  
  • No protective antibody response identified​
• 130–150 million people globally have chronic hepatitis C infection.
• Approximately 500 000 people die each year from hepatitis C-related liver diseases.
• HCV Diagnostics
  
  • Both serology and NAT assays needed for most accurate and timely diagnosis.
  • HCV ELISA: Using recombinant c22-3, c200, and NS5 proteins.
  • No IgM assay: IgM is problematic, often transient.
  • PCR (Qualitative for screening and quantitative for monitoring treatment effectiveness).
• ​7 genotypes
• >60 subtypes
• Genotyping used for both treatment algorithms and outbreak investigations.
• Zepatier, a combination of elbasvirand grazoprevir, with or without ribavirin earned FDA approval. Trials demonstrated sustained virologicresponse (SVR) rates of up to 97 percent in genotype 1 patients and up to 100 percent in patients with genotype 4.
  Treatment

Question 62

Respiratory Infections

Answer 62

• “Common Cold” ( coryza )
  
  • Acute, mild, self-limiting catarrhal syndrome
  • Upper respiratory infection
  • Rhinorrhea (runny nose)
  • Nasal congestion
  • Sore throat
  • Sneezing
  • Coughing
• Croup, Bronchiolitis, and Pneumonia
  
  • Lower respiratory infection

Question 63

Respiratory Infections : Croup

Answer 63

• Laryngotracheobronchitis
• Barking cough
• Typically associated with parainfluenza viruses, but can be caused by other viruses and bacteria

Question 64

Bronchiolitis

Answer 64

• Common lung infection in young children and infants
• Inflammation and congestion of bronchioles
• Almost always caused by a virus
• Initially symptoms similar to common cold
• Progresses to coughing, wheezing and sometimes difficulty breathing
• Caused by a variety of viruses, including those that cause the flu or the common cold
• Contagious: transmitted by aerosol droplets from infected individuals
• Virus infects the bronchioles
• Bronchioles become swollen and inflamed
• Mucus collects in airway and breathing becomes difficult
• Risk factors: < 6 months old, premature,
• exposure to tobacco smoke, not breastfed, daycare setting, underlying medical condition
• Viral agents: RSV, HMPV (also PIV3)
• Respiratory syncytial virus = RSV

Question 65

Pneumonia (lung inflammation)

Answer 65

• Inflammation from infection of one or both lungs
• Can be caused by >30 different infectious agents
• Critical to know the cause for effective treatment
  
  • Role of laboratory
• Symptoms: cough, fever, chills, and trouble breathing
• (dyspnea); fatigue, sweats, headache, nausea, myalgia
• Alveoli become inflamed and fill with fluid and pus
• Decrease in O2 delivery throughout the body –> ARDS –>death
• Determine if Bacterial or Viral is imperative

Question 66

Overview of viral infections

Answer 66

Question 67

Respiratory Virus Transmission

Answer 67

• Direct contact with secretions
• Autoinoculation from contaminated hands to mucus membranes (eyes, nose, or mouth)
• Aerosol transmission - Direct inhalation
  
  • Large droplets ( 5um)
  • Small particles (<5um) - can stay suspended in air for longer periods of time than large droplets
• Indirect contact with inanimate objects (fomites) contaminated with respiratory secretions

Question 68

*Laboratory Detection
of Respiratory Viruses*

Answer 68

• Virus isolation by cell culture
• Antigen detection by DFA
• Electron microscopy
• Molecular detection by PCR single plex OR multiplex assays
  
  • Real time RT PCR (RNA viruses)
  • Real time PCR (DNA viruses)
• Typing for epidemiology/surveillance
• Sequence analysis or serotyping (Rhino, EV, AdV)
• Timing, specimen choice & patient age
• Impact success of testing
• Maximal virus shedding: 3-5 days post-onset
• Nasopharyngeal specimens usually contain high
• titers of virus and infected cells

Question 69

Respiratory Culprits

Answer 69

• Orthomyxoviridae (negative ssRNA )
  
  • Influenza A and B [Hugo’s lecture]
  • Influenza C (mild symptoms, no epidemics)
  • Influenza D (newly described from cattle)
• Paramyxoviridae (negative ssRNA )
  
  • Respiratory Syncytial Virus (RSV)
  • Human Metapneumovirus (
  • Parainfluenza virus 1 (PIV 1)
  • Parainfluenza virus 2 (PIV 2)
  • Parainfluenza virus 3 (PIV 3)
  • Parainfluenza virus 4 (PIV 4)
• Coronaviridae (+ ssRNA )
  
  • Coronaviruses [6 species affecting human]
• Picornaviridae (+ ssRNA , non enveloped)
  
  • Enterovirus (several types)
  • Rhinovirus (several types)
• Adenoviridae (dsDNA, non enveloped)
  
  • Adenovirus (1 through 65) [ AdV

Question 70

Respiratory viruses - Enveloped, negative-sense ssRNA

Answer 70

• Influenza type A and type B
  
  • Cause seasonal epidemics of disease (flu season) almost every winter
  • Influenza A viruses may cause flu pandemics, i.e., global epidemics of flu disease
  • when a new and very different influenza A virus emerges that can infect people and spread efficiently between people
• Influenza type C
  
  • mild illness and are not thought to cause human flu epidemics
• Influenza type D
  
  • primarily affect cattle
  • not known to infect or cause illness in people

Question 71

Influenza Virus

Answer 71

• Family Orthomyxovirus
• Genus Influenza
• Negative strand RNA virus
• Segmented genome

Question 72

Respiratory Syncytial Virus (RSV)

Answer 72

• Paramyxoviruses: Genus Pneumovirus
• Most infected by 2 yrs of age
• RSV leading cause of acute LRT illness in infants and young children worldwide
• Bronchiolitis and pneumonia in infants
  
  • LRT illness in elderly: morbidity and mortality
  • Subgroups A and B
  • The impermanence of immunity to RSV reinfection
  • Can be difficult to isolate via cell culture
  • mAB used for prophylaxis for high-risk children (approved in
  • Vaccine development: challenging
  • 1966 vaccine: enhanced illness in children and caused 2 deaths
  • Structure of Fusion (F) protein solved 2013 - Stable preF for vaccines
    *

Question 73

Human Metapneumovirus (HMPV)

Answer 73

• Paramyxoviruses: Genus Metapneumovirus
• 1st described in 2001
• A common virus which infects most by the age of 5 10 yrs
• An important cause of bronchiolitis in young children
• Neurologic involvement can occur
• Reinfection can occur
• Severe disease can result in elderly
• Subgroups A and B (4 lineages)
• Very labile; slow to amplify in cell culture, requires trypsin

Question 74

_***Paramyxoviruses
Parainfluenza Viruses (human)***_

Answer 74

• Genus Respirovirus : PIV 1 and 3
• Genus Rubulavirus : PIV 2 and 4
• Infect most by the age of 5 years
• “Para” flu - similar to flu: symptoms (fever) and hemagglutination of RBCs (HA and NA activity)
• Most common cause of croup worldwide
• Bronchiolitis and pneumonia in infants/young children
• Reinfection does occur, usually milder than primary
• 3rd or 4th common cause of URT infections in young
• Mostly mild and self limiting
• Otitis media or sinusitis may occur
• Fever in up to 75% patients
• About 15% cases result in LRT infections - CROUP
• PIV 1 causes ~50% of all croup cases (6 mos to 6yrs old)
• PIV 3 - bronchiolitis/pneumonia < 1 yr (severe)
• PIV 1 usually more cases in the fall of odd years
• PIV 2 occurs more commonly in the fall each year
• PIV 3 infections usually occur in the spring and early summer months
  
  • NOTE: PIV 3 infections can occur throughout the year, particularly when PIV 1 and PIV 2 are not in season.
• PIV 4 seasonal patterns are not as well characterized.

Question 75

Picornaviridae

Answer 75

• Respiratory (+) ssRNA viruses and disease
• Enterovirus genus (15 species: 7 human specific)
  
  • Aseptic meningitis, respiratory illness, acute flaccid
  • paralysis, Hand/Foot/Mouth disease
  • EV 4 species [virus example]:
  • Human enterovirus A [Coxsackievirus A]
  • Human enterovirus B [Coxsackievirus B and echovirus]
  • Human enterovirus C [ Poliovirus
  • Human enterovirus D [EVD 68]
  • Fecal oral and respiratory transmission routes
• Rhinoviruses
  
  • Rhino = nose
  • The most common cause of the “common cold”
  • 3 species:
    
    • HRV A (77 types), HRV B (25 types), HRV C (49 types)
  • HRV C was discovered in 2006; LRT illness in young
  • Can cause LRT illness, esp in asthmatic children and the elderly
  • Croup, bronchiolitis, tracheobronchitis , flu like syndrome
  • Asymptomatic infections are frequent
  • Will not amplify in nonhuman cell lines
  • HRV C: nonculturable
  • Acid labile (vs Enteroviruses)

Question 76

Coronaviridae

Answer 76

• Respiratory (+) ssRNA viruses and disease
• Large nonsegmented RNA genome: 26 32 kb
• Most infected by 6 yrs of age ( HCoVs) Common Cold
  
  • HCoV 229E and OC43: URTIs
  • LRTIs in high-risk patients (young or immunocompromised)
  • HCoV NL63: URTIs and croup
  • HCoV HKU1: URT and LRT infections
  • Also detected in stool from patients with respiratory and enteric disease
• Novel Pneumonia- Anosmia (loss of smell and taste) not Flu
  
  • Coronavirus emerging infections
  • Severe Acute Respiratory Syndrome (SARS CoV 2) 2019 - ongoing)
  • Middle East Respiratory Syndrome (MERS CoV) 2012 - now)
  • Severe Acute Respiratory Syndrome (SARS) ( 2003 - extinct)

Question 77

Adenoviridae: Adenoviruses

Answer 77

• First described in 1953, more than 60 types described
• Very hardy viruses - non enveloped DS DNA LINEAR
  
  • environment, gastric secretions, pancreatic proteases
• Common URT infections: “common cold”, other resp symptoms
• (throat, ear, conjunctiva); fever
• Young/immunocompromised: severe disease including
• pneumonia, hepatitis, meningitis, encephalitis
• Severe/fatal cases associated with AdV 7 and 14
• all ages, healthy
• Conjunctivitis (pinkeye) and Epidemic keratoconjunctivitis ON TEST
• Extended length of viral shedding (resp and fecal)
• Adenoviruses: Typing
  
  • Serotyping by neutralization
    
    • Requires cell culture and specific AdV antisera
    • Major neutralizing epitope located in the hexon protein
  • Molecular typing
    
    • Based on hexon and fiber genes
    • Fiber: group determination
    • Hexon: type determination

Question 78

Sars-CoV-2

Answer 78

• Incubation period:
  
  • 2-14 days after exposure
• Asymptomatic to severe respiratory illness and beyond
• Symptoms (similar to flu) may include:
  
  • Fever, cough, sore throat, fatigue
  • Headache
  • Muscle aches
  • Nausea/vomiting, diarrhea
  • Pneumonia, shortness of breath
  • Anosmia (loss of smell and taste) not Flu
• ​Complications
  
  • Lung opacities (x ray)
  • Pneumonia
  • Long COVID
  • Heart involvement
  • Blood clotting (coagulopathy)
  • Multisystem Inflammatory Syndrome Children (MIS C)
  • Multisystem Inflammatory Syndrome Adults (MIS A)
  • Neurologic involvement?

Question 79

Middle East Respiratory Syndrome (MERS-CoV)

Answer 79

• First identified in humans in 2012
• MERS illness spectrum
  
  • Asymptomatic to mild respiratory illness
  • Severe pneumonia with ARDS
  • Death
• Symptoms
  
  • Fever, cough, chills, sore throat
  • Shortness of breath with rapid progression to pneumonia within the first week
  • Gastrointestinal symptoms (33%), ARDS, kidney
  • failure, and death
• Risk factors for severe illness:
  
  • Pre existing condition (comorbidity)
  • Immunocompromised state
  • Obesity
  • Diabetes
  • Chronic lung, heart, or kidney disease
  • >3,000 cases
  • 65% male; median age=50 years
  • Case fatality rate ~36% (60% with co morbidities)
• No vaccine, no specific antiviral treatment
• Incubation period:
  
  • 9-12 days
  • Range 2-14 days
• Strong evidence linking dromedary camels (DCs) as major reservoir host for MERS CoV
  
  • More than 90% of adult DCs are seropositive for MERS CoV
  • Detection of MERS neutralizing ABs in DCs from several
  • different countries in the region (including African countries)
• 3,000 MERS cases
  
  • Very few report camel contact
  • ~60% of MERS cases via nosocomial spread
  • ~40% unknown origin
• Recommended Specimens for MERS testing
  
  • Lower Respiratory Tract.
    
    • Highest virus titers
    • BAL, tracheal aspirate, or induced sputum
  • Upper Respiratory Tract
    
    • NP or OP swab in VTM
• Serum
  
  • PCR
  • Serology, if indicated
• Confirmed MERS case defined as:
• Laboratory test positive for MERS CoV
  
  • Real time RT PCR assay
• Authorization)CDC Assay (FDA Emergency Use
  
  • UpE and N2 targets: screening specimens for MERS
  • N3 target: confirmation of MERS
  • R P target: control for specimen quality
  • VTC & NTC: positive and negative controls
• No Vaccine Available

Question 80

Norovirus (enteric)

Answer 80

• Caliciviridae family
  
  • non-enveloped, icosahedral
  • Single-stranded RNA (positive sense, ~7 KB)
  • 27-35 nM
  • “Calyx”-Latin, cup-shaped
  • Genogroups I and II most commonly associated with human outbreaks
• Leading cause of viral gastroenteritis in the US
  
  • Potential for large outbreaks
  • 800 deaths (due to underlying illness), 70,000 hospitalization, 21 million cases yearly in the US
  • emergence of pandemic strain every 3-4 years
  • No vaccine/antiviral
  • Illness from mild to life-threatening complications (young, elderly, immune compromised, other illness);
  • Illness length varies: days (longer in some)
  • Not a reportable disease
  • Large societal/economic cost
• Norovirus Shedding and Infection
  
  • ​Low infectious dose (1-20 particles)
  • High level of shedding (10^7 particles or more per gram of stool)
  • Incubation: 1.5 days
  • Duration of symptom: one day or more
  • Prolonged shedding—up to two weeks
  • Chronic shedding (immuno-compromised)
  • Environmental persistence (very hardy)
  • Transmitted fecal orally
  • Poor immune response due to genotypic diversity
• Human norovirus targets enteroendocrine epithelial cells in the small intestine
• Epidemiology
  
  • ​70-80% of epidemic outbreaks in communities: schools, institutions (senior facilities, jails), camps, catered events and families
  • Person-to-person transmission—90% of all outbreaks
  • Foodborne transmission-10% (or more not reported?)
  • Common food source—oyster (filter feeder), berries (?)
  • Natural reservoir—Human
  • Winter seasonality (October to May) but Outbreaks can happen any time
• Promote appropriate hand hygiene
  
  • Wash with soap and waterfollow with Alcohol-based hand sanitizers
  • Single use gloves
  • Prompt and thorough disinfection
  • 1:10 Bleach solution for contaminated surfaces 15 minutes
  • Use of additional sanitizer/disinfectant when bleach can’t be used
  • –Exclude ill workers
  • Accommodating sick pay/leave policies
  • >48-72 hrs after symptoms resolution
  • Non-food handling activities and reinforced hand washing upon return
• –Treatment
  
  • Oral rehydration salt (ORS)
  • Antimotility and antisecretory agents (adults)
  • Antivirals?
• Lab Diagnosis
  
  • Electron microscopy—need high viral load and good morphology, skilled microscopist, equipment
  • ELISA –antigen detection—not as sensitive
  • PCR-real time and conventional
  • Real time PCR: 2 hours, extremely specific and sensitive—genogroup specific
  • Sample type:
  • Stools (high viral load)
  • Vomitus (low viral load)
  • No environmental sampling
  • No food testing at VRDL
  • Multiplex Platforms such as Cepheid GenXpert or Biofire
    
    • Timing: collected within 48-72 hours of onset for highest viremia
    • Number of specimens per OB: minimum 3, up to 10 (Need more than 2 virus positive samples to define an outbreak)
    • Shipping: cold packs
    • Storage (if not tested right away): 4°C for 3 days, -70°C or below to prevent bacteria and mold growth (which will degrade virus)
    • No preservative such as PVA or formalin (for parasite)

Question 81

Sapovirus (enteric)

Answer 81

• Caliciviridae family
• Morphology: similar to norovirus
• Not enveloped
• Discovered in Sapporo, Japan in 1997
• Test: PCR
• Associated with outbreaks, but less common than norovirus
• But very diverse: need new primer/probe design (Diez-Valcarce et al, JCV 2018)

Question 82

Rotavirus (enteric)

Answer 82

• Family Reoviridae (Respiratory Enteric Orphan)
• Leading cause of gastroenteritis in young children, 6 months to 6 years of age in the world, leading cause of childhood mortality in the third world countries
• Rotavirus A most common
• non-enveloped, 11 segments double-strandedRNA
• Rotavirus infection can still happen in adults (CDPH and Local PH publication in MMWR 04/27/18)
• Diagnosis
  
  • EM: need high level of shedding (>10^8 particles/gram)
  • EIA: high level of antigens ideal for EIA capture, mostly used in clinical laboratory
  • PCR: real time, limited to specialized labs, but more sensitive
  • Cell culture: need specialized cells such as MA104 (monkey kidney epithelial cells)
• Rotavirus Vaccine
  
  • RotaTeq and Rotarix
  • CDC recommended vaccination of infants (3 doses of oralvaccine at 2, 4, 6 months)
  • 74% to 87% effective in preventing illness

Question 83

Adenovirus 40/41

Answer 83

• Adenoviridae family
• Serotypes Ad 40 and 41; group F
• typical adenoviruses (DNA virus, icosahedral, not enveloped)
• fastidious, grow only in special cell line such as Graham’s HEK-293T (human embryonic kidney cells)
• 5-7% of diarrhea in children
• Test: EM, EIA, PCR, culture

Question 84

Astrovirus (enteric)

Answer 84

• Astroviridae family–“star” on surface of virion
• Small, non-enveloped, ss RNA
• 1-10% GI infections in children 1-5 years of age; development of immunity
• more common in cooler months; rain season (in third world countries)
• Grow in cell culture (need special cells such as Caco-2—human colorectal adenocarcinoma epithelial cells)
• Test: EM, ELISA, culture, PCR
• Possible neurologicalinvolvement with type VA-1

Question 85

Poxviruses

Answer 85

• Members of Poxviridaefamily
  
  • Entomopoxvirinae(insect poxviruses) –infect arthropods
  • Chordopoxvirinae(vertebrate poxviruses) –infect vertebrates
• Species from only 2 genera transmit exclusively human-to-human –Molluscipox Orthopox
• Variola(Orthopox) and Molluscumcontagiosum(Molluscipox) are sole human pathogens i.e. transmit human-to-human only, no animal reservoir
• dsDNA virus, ~135-200 kbp, cytoplasmic replication, brick-shaped, Enveloped
  
  • Encode 200+ proteins (viral life cycle, structural, immune evasion, host range, etc.)
  • 95% nucleotide identity amongst species
  • 93% conservation of AA surface antigen
  • Antigenically similar; serologic cross-reactivity
  • Contributes to efficacy of smallpox (vaccinia) vaccine
• Stable in dry environmental conditions; maintain infectivity for many months

Question 86

Transmission of Smallpox

Answer 86

• Through inhalation of airborne variola virus, usually, droplets expressed from the oral, nasal, or pharyngeal mucosa of an infected person.
• Or from physical contact with a person with smallpox or with contaminated particles.
• A person with smallpox is sometimes contagious with the onset of fever (prodromephase), person becomes most contagious with the onset of rash. The infected person is contagious until the last smallpox scab falls off.

Question 87

Smallpox Clinical Symptoms

Answer 87

• Fever >101°F 1-4 days prior to rash onset, headache, backache, chills, vomiting or severe abdominal pain
• Firm deep-seated, well-circumscribed vesicle/pustules, umbillicated
• Lesions in the same stage of development in any one part of the body
• Centrifugal distribution (greatest concentration of lesions on face and distal extremities including palms and soles)
• Toxic or moribund appearance
• First lesions in oral mucosa, face or forearms
• Smallpox Treatment
  
  • Antivirals are being researched but nothing is currently available (cidofovir-nucleotide analog; DNA pol inhibitor)
  • Supportive therapy (i.e. IV fluids, medicines to control fever and pain)
  • Antibiotics for any secondary infections that may occur
• Smallpox Vaccine
  
  • Live attenuated Vaccinia virus –ACAM2000SanofiPasteur
  • Immunity for 3-5 years decreasing thereafter
  • Cross-protective against other Orthopoxviruses
  • Bifurcated needle that scabs over and scars
  • Used as post-exposure prophylaxis –within 3 days prevents or significantly lessens disease, within 4-7 days some protection and may modify severity
  • Recommended for laboratory workers by ACIP

Question 88

Lab DxMethods for Orthopox Diagnosis

Answer 88

• DFA, PCR, Culture, Serology and EM
• Differentiation from other conditions/illness Centrugal POX versus centripetal chicken pox
• VZV, HSV, enteroviruses, MCV, Scabies, rickettsialpox(R. akari)
• Follow LRN algorithms and protocols
• Real-Time Orthopox PCRs target the DNA-pol (E9L) or HA genes
  
  • LRN Variolareal-time PCR -(High-risk samples)
    
    • -Detects only variola
  • LRN Orthopox Generic real-time PCR –(Moderate risk samples)
    
    • -Detects all Eurasian orthopoxviruses including variola
    • -Detects all North American orthopoxviruses including variola
• Virus culture –gold standard; performed by CDC
• Serology–EIA, IFA, and others; -performed by CDC
• Specimens
  
  • Lesion “roofs,” crust/scabs –best specimen
  • Vesicular fluids–touch prep on slide
  • Fresh Biopsy –No formalin
  • Dry or Wet Swab of Lesion –Dry is preferred
  • 10^6 pock forming units in skin lesions by day 2 of rash and largely persist to day 10 of rash [Kitamura et al, 1977]

Question 89

Influenza Antivirals

Answer 89

• adamantases: M2 blockers
• neuraminidase inhibitors
• CEN- inhibitor
  
  • Blocks the negative sense RNA
• M2 inhibitors for the treatment of influenza A infections
• Amantidine & Rimantidine, are not recommended due to widespread resistance among circulating influenza viruses.
• Neuraminidase (NA) inhibitors (NAIs) for the treatment of influenza A and B infections:
  
  • Oseltamivir (oral)
  • Zanamivir (inhaled)
  • Peramivir (intravenous)
  • NAI’s blocks NA activity (cleavage of sialic acid) and stops viral
    propagation
  • Effective against Influenza A&B
  • Resistance of Flu A to Tamiflu is associated with an amino acid substitution at positions 274 of N1 protein (H275Y) and N2 protein (H274Y)
• cap-dependent endonuclease (CEN) inhibitor for the treatment of influenza A and B infections Baloxavir (oral)

Question 90

NI Assay

Answer 90

• The functional NA inhibition (NI) fluorescent assay is the preferred method for the detection of resistance to the NAI class of drugs caused by established (e.g., H275Y) or novel mutations.
• This method is performed on influenza virus isolates.
• In order to effectively expand domestic surveillance capabilities and improve the exchange of drug susceptibility data, the fluorescent NI assay was implemented at CDC and three public health laboratories (PHLs)
• The interpretation of drug susceptibility data is expressed in IC50 values (the drug concentration required to inhibit 50% of viral NA enzyme activity).

Question 91

Hemagglutination Assay (HA)

Answer 91

• Influenza HA molecule binds to sialic acid-containing receptors such as those found on the membrane of red blood cells (RBC’s).
• When RBC’s are mixed with Influenza virus the it bridges the RBC and changes their normal settling pattern. This interaction is called hemagglutination (HA).
• Hemagglutination = lattice formation (cross-linking that occurs when virus is bound to RBCs)
• Non-agglutination = Settled pattern (No virus exists to attach to RBCs). RBCs are free to fall out.
• Specific antibodies against the influenza HA glycoproteins will inhibit the cross-linking between RBC’s and virus. This effect is called hemagglutination inhibition (HI).
• Influenza virus isolated from a positive clinical specimen
  (patient)
• Titrated red blood cells (guinea pig/turkey) as indicator

Question 92

Uses of Cell Culture in Diagnostic Virology

Answer 92

• Isolation and identification of viruses (CPE and immunofluorescence looking for antigens)
• Production of viral antigen
  
  • Vaccines
  • To make antiserum
  • Antigen for various testing systems, e.g. FA slides, EIA
• Assays to detect antibodies to specific viruses
  
  • Neutralizing antibody assays, plaque assay

Question 93

Characterization of Cells in Culture

Answer 93

• Primary: culture taken directly from cells or tissue of an organism NOT sub cultured
• Cell line: a propagated culture after the first subculture
• Finite cell line: Diploid, capable of a limited number of cell divisions
• Continuous cell line: usually not diploid, can be cultured indefinitely in vitro (transformed cells) example: HeLa cells

Question 94

*Types of Specimens
(possible viruses)*

Answer 94

• Stool or rectal swabs :
  
  • EV, AdV, Norovirus, Rotavirus, other Reovirus, etc.
• Urine sediment and cells:
  
  • Measles, Mumps, CMV
• Eye Swabs:
  
  • AdV , HSV, CMV, rarely EV 70, CAV 24
• Saliva:
  
  • Mumps, Rabies
• CSF:
  
  • EV, rarely HSV, Arbovirus; CMV, VZV, AdV in immunocompromised, WNV
• Blood:
  
  • CMV in buffy coat
• Organs: lung
  
  • (CMV, HSV, AdV , PIV, Flu)
• brain
  
  • (HSV, EV, HIV, rarely Epstein Barr Virus (EBV), Arboviruses: Flavi –, Toga –, Bunyaviridae ,
• heart
  
  • (EV, AdV , CMV)
• liver, spleen
  
  • (rarely CMV, HSV)

Question 95

Virus Induced Structural Changes (types of CPE)

Answer 95

• Change in cell morphology
  
  • Cell rounding
  • Degeneration
  • Aggregation
  • Loss of attachment of the substrate
• Histologic
  
  • changes
  • Inclusion bodies in the nucleus or cytoplasm.
  • Migration of chromatin
• Syncytia formation
  
  • Multinucleated giant cells caused by the virus-induced cell-cell fusion
• Change in cell surface
  
  • Viral antigen expression
  • Hemadsorption (hemagglutinin) expression

Question 96

Hemadsorption (Had) test

Answer 96

• Hemadsorption occurs on a cell sheet with a cell associated virus that expresses a protein to allow for RBC’s to stick to the virus
• Hemagglutination occurs with free virus and RBCs attaching
• Sources of susceptible RBCs
  
  • Guinea pig Cells
  • Human “O” Cells
  • Chicken Cells
  • Goose cells
  • Monkey cells
  • Rat cells
• Hemadsorption (Had) Positive
  Viruses
  
  • Mumps
  • Measles
  • Influenza A and B
  • Parainfluenza Types 1-4

Question 97

Herpesviruses HSV 1 and 2 CPE

Answer 97

• TORCH agent
• Ballooning degeneration in 1 3 days
• Focal CPE initially but soon involving whole cell sheet
• Prefers HFDL cells but can grow in PMK
• Also A549, MRC 5

Question 98

Varicella Zoster Virus (VZV) CPE

Answer 98

• Scattered foci of enlarged rounded cells at 3 7 days which degenerate
• Nuclear inclusions (Cowdry A), eosinophilic

Question 99

Cytomegalovirus(CMV) CPE

Answer 99

• TORCH agent
• Small foci of small rounded cells which lasts for days
• Average growth rate
• 10-14 days (up to 28)
• Prefers HFDL ( remains focal)
• Nuclear inclusions (Owls eyes) in renal tubular cells, basophilic

Question 100

Adenovirus ( AdV) CPE

Answer 100

• Prefer A549, form rounded cells in 2 7 days
• HFD less sensitive, CPE 7 14 days; egg-shaped swollen cells
• Grow in RMK only if SV40 present; clumps (grape-like clusters) in 2-7 days
• Enteric AV40, 41 difficult to cultivate; may grow in HEp 2 o Graham 293 cells

Question 101

Picornaviruses CPE

Answer 101

• Rhinoviruses
  
  • Prefer HFDL
    
    • grow in 2 7 days as delicate rounded cells of various sizes with many very small cells
  • Requires 33C on primary isolation
  • May “roughen” cells on primary isolation; pass cells for typical CPE
  • Acid labile
  • More than 100 serotypes
• Enteroviruses
  
  • Some types prefer RMK
  • ie Coxsackie B
  • Produce rounded or teardrop retractile cells in 2 5 days
  • Routine diagnostics: RD (human rhabdomyosarcoma) and L20B (transgenic mice cell line) for polioviruses
  • Many grow in HFDL cells ie Echovirus
  • 67 serotypes:
    
    • Polio –, coxsackie A –, coxsackie B –, echovirus, enterovirus
  • Acid stabile

Question 102

Orthomyxoviruses: Influenza A and B CPE

Answer 102

• Grows in RMK or MDCK cells in 4-8 days CPE may heal
• Degenerative CPE, not uniform or round, cells may appear “double-walled”
• Hemadsorption (Had) may precede CPE

Question 103

Paramyxovirus: Parainfluenza viruses 1-4 CPE

Answer 103

• RMK cells most sensitive, grows in 4-10 days
• PIV1 and 4 have little or no CPE
• PIV2 may form syncytia
• PIV3 may form “splinters” or “ Had at 4 o C (PIV4 Had better at 36 o C)

Question 104

Paramyxovirus: Respiratory Syncytial Virus(RSV) CPE

Answer 104

• Fairly labile virus
• Grows in variety of cells: PMK, human epithelial, human fibroblast
• Large syncytia in 3 7 days, very granular in HFDK
• Direct detection may be more sensitive than isolation
• Does not Had

Question 105

Paramyxovirus: CPE

Answer 105

• Mumps
  
  • Forms syncytia in RMKin 7 10 days
  • Hemadsorbs
  • Specimens of choice:
    
    • Parotid Gland
    • Buccal swab
    • Urine
• Measles(Rubeola)
  
  • Prefers B95a or VeroSlam
  • but will grow in RMK
  • Forms syncytia or large stellate cells in 7 10 days
  • Incubate for total of 21 days w/ 2 blind passes
  • Virus light sensitive
  • Can be isolated from NP swab up to 2 days, in urine 1 week or more after rash appears
  • Cell associated virus

Question 106

Togavirus : Rubella (German Measles) CPE

Answer 106

• TORCH agent
• Vero/Slam or BHK cells
• No or minimal CPE
• May require up to 3 passages for negative; blind stain. PCR is frequently used now.
• In nasopharynx up to 14 days after rash but infants may excrete for longer.
• Urine sample is of value

Question 107

Grading of CPE

Answer 107

• Cellular Degeneration
• Microscopic readings of cytopathic effect (CPE) are graded from 0 to ++++
• 0
  
  • No CPE
• 0+/-
  
  • Suspicious (one patch of CPE/cell sheet typical??)
• +
  
  • A few patches of CPE/cell sheet
• +
  
  • 25% cellular degeneration (a few patches of CPE/field)
• ++
  
  • 50% cellular degeneration (underlying cell sheet still intact)
• +++
  
  • 75% cellular degeneration (a few normal cells present holes in sheet)
• ++++ 100%
  
  • cellular degeneration (no normal cells present cell sheet nearly gone)

Question 108

Based on CPE you can perform:

Answer 108

• Endpoint dilution assay to calculate virus infectious titer or TCID50 (tissue culture infectious dose 50) = the amount of virus required to produce a cytopathic effect in 50% of inoculated tissue culture cells.
• Plaque assay determine the number of plaque forming units (PFU) for virus quantity
• Focus forming assay (FFA) fluorescently labeled antibodies specific for a viral antigen to detect infected host cells and infectious virus particles before an actual plaque is formed

Question 109

*Length of Incubation Before Report out as Negative
(conventional culture)*

Answer 109

• 7 days for HSV
• 14 days for most other viruses
• 28 days for CMV
• 3 7 days for continuous cell lines
• Blind passage (2x): additional passage if no CPE (freeze/thaw, routinely done, e.g. polioviruses and other enteroviruses, after 7 days)

Question 111

Retroviruses

Answer 111

• 2x single stranded RNA
• Enveloped
• Binding to host cell surface receptors by viral envelope glycoproteins, insertion
• Reverse Transcriptase
• Integrase
• Protease
• Reverse transcription of retroviral RNA into dsDNA and insertion into the host cell DNA (provirus)
• Host cell transcription to RNA and translation of viral poly-protein
• Directly cytopathic (HIV), malignancy (HTLV-I)

Question 112

Anti-Retroviral Therapy

Answer 112

• Entry inhibitors
• Nucleoside/nucleotide reverse-transcriptase inhibitors –dysfunctional nucleoside/nucleotide analogues
• Non-nucleoside reverse-transcriptase inhibitors –bind directly to RT
• Integrase inhibitors
• Protease inhibitors
• Combination therapy -undetectable levels of HIV

Question 113

HIV Tests

Answer 113

• Rapid tests
  
  • Tests require less than 30 minutes to perform
  • Point of care, outreach
  • Low/Moderate complexity
  • 1992 First FDA approved HIV rapid test
  • Require confirmation
• Laboratory Screening tests
  
  • EIA/CIA, (IFA)
  • Higher complexity
  • Better sensitivity and specificity
• Confirmatory tests
  
  • Western blot, IFA, Geenius, RNA
  • More specific
  • Some differentiate HIV-1 and HIV-2

Question 114

4th generation EIA HIV

Answer 114

• Detects
  
  • P24 antigen
  • HIV antibodies
• More sensitive

Question 115

Western blot Confirmatory test HIV

Answer 115

• Confirmatory test example
• Western blot
• HIV-1 critical bands:
  
  • p24
  • gp41-Transmembrane
  • gp120/160-Outer Glycoprotein
• CDC/APHL HIV-1 western blot criteria:
  
  • Positive: At least two of three –p24, gp41, gp120/160
  • Indeterminate: Any band pattern that does not meet the criteria for a positive result
  • Negative: No Bands

Question 116

Confirmatory test example –HIV RNA

Answer 116

• AptimaQualitative HIV-1 RNATranscription mediated amplification
• Isothermal
• RNA polymerase and Reverse Transcriptase
• RNA amplicon
• Validated HIV-1 viral load –Not transferable between laboratories
• HIV-2 RNA? –None FDA approved

Question 117

HTLV-I Diseases

Answer 117

• ATL - Adult T Cell Leukemia/Lymphoma
• TSP/HAM - Tropical Spastic Paraparesis/HTLV-1 Associated Myelopathy

Question 118

HTLV-1 ATL

Answer 118

• Malignancy of T-Cells
• Progression to ATL in 1% - 5% of HTLV-1
• infected individuals
• Long incubation period (20-30 years)
• Usually Rapid, Fatal course (2-3 mos.)
• Occasionally Chronic “smoldering”

Question 119

HTLV-I Disease - TSP/HAM

Answer 119

• Immune mediated, progressive, chronic myelopathy
• (degenerative disease of the spinal cord)
• 1-2% of HTLV-I infected individuals
• Shorter latency than ATL (3 to 4 years from exposure by transfusion)
• Impairment of motor and/or sensory function of lower
• extremities, Hyperreflexia, Muscle weakness, Sphincter disorders affecting urinary bladder and intestines, Uveitis (middle tissue layer of the eye)

Question 120

HTLV Transmission

Answer 120

• Endemic areas: Breastfeeding
• Exposure to blood and blood products
• Sharing of infected needles
• Sexually
• HTLV-II
  
  • Not widely recognized as a disease causing agent
  • Cross reaction with HTLV-I (70% sequence homology with HTLV-1)

Question 121

HTLV-I/II Testing

Answer 121

• Enzyme immunoassay (EIA) - FDA approved
• Western Blot (WB) - FDA approved, VRDL
• Immunofluorescence Assay (IFA) - VRDL
• Radioimmunopreciptation Assay (RIPA) - VRDL
• Polymerase Chain Reaction (PCR) – Some commercial labs
• Remember
  
  • Only HTLV-I causes diseases: ATL and TSP/HAM
  • Infection with HTLV-I or II can be differentiated serologically by IFA endpoint dilution

Question 122

HIV-1 WESTERN BLOT TECHNIQUE OUTLINE

Answer 122

1. PREPARE ANTIGEN - Purified lysate of HIV cell culture, with
   or without recombinant proteins added.
2. DISRUPT ANTIGEN – Heat denature and reduce disulfide bonds,

SDS (uniform negative charge).

3. RESOLVE HIV-1 PROTEINS BY ELECTROPHORESIS IN
   POLYACRYLAMIDE GEL
4. TRANSFER RESOLVED PROTEINS FROM GEL TO
   NITROCELLULOSE
5. CUT STRIPS AND INCUBATE WITH SPECIMENS
6. IDENTIFY POSITIVE REACTIONS BY ENZYME
   IMMUNOASSAY

• HIV-1 WESTERN BLOT
  
  • Major bands of diagnostic significance: 2 of 3 for a positive
    
    • p24
    • gp41
    • gp120/160