Micro Basics

Question 1

What are the four types of viral RNA structure?

Answer 1

+ssRNA, -ssRNA, dsRNA, and circular -ssRNA

Question 2

What are capsids?

Answer 2

proteins shells that hold viral nucleic acid

Question 3

What are the main types of capsids?

Answer 3

helical, icosahedral, and complex

Question 4

Describe helical capsids.

Answer 4

concerted assembly in which proteins of the capsid bind to nucleic acid as the nucleic acid alpha helix is being constructed (all happening at the same time). Proteins don’t spiral because they are bound to the alpha helix structure. Length of the capsid is determined by the length of the nucleic acid helix

Question 5

Describe icosahedral capsids.

Answer 5

These are made in a sequential mechanisms known as headful packaging. Triangle shaped monomer proteins self-assembly to form pentamers and then those will self-assembly to form a pro-capsid, which has gaps for nucleic acid insertion. Following nucleic acid insertion, the mature capsid will form and seal. called headful because the size of the capsid is made to fit one genome inside. If the genome is too large, pressure will build and the capsid will burstmaximizes volume to surface area without internal support needed

Question 6

What are naked viruses?

Answer 6

genome+ capsid= nucleocapsid is the final structure with no envelope. Commonly have spike proteins for attachment and are virulent in that form

Question 7

What are enveloped viruses?

Answer 7

Some viruses have lipid envelopes that are derived from cellular membranes so the nucleocapsid is not the infectious portion. Loss of the lipid envelope causes loss of infectious nature. In the envelope, the protein content (typically glycoproteins) are encoded by the virus themselves and inserted in the envelope. These mediate virus attachment and integration, so the loss of the envelope is bad for the virus.never stable in GI and require a wet environment for spread

Question 8

What are the main steps of virus replication?

Answer 8

1) attachment and penetration2) uncoating3) early transcription and synthesis of nonstructural proteins (for DNA and RNA viruses)4) genome replication5) late transcription and synthesis of structural proteins6) assembly and release

Question 9

What are the two main ways viruses enter cells?

Answer 9

endocytosis (ph-dependent) and plasma membrane fusion (ph-indepedent)

Question 10

How does viral endocytosis work?

Answer 10

Enveloped virus (most naked viruses use this route) attaches to the surface via spike proteins and invaginate into the cell in an endosome. As the endosome matures from an early to a late endosome, the pH lowers, triggering conformational changes in the protein coat of the virus and it fuses with the endosome, releasing the nucleic acid into the cell.

Question 11

How does plasma membrane fusion work?

Answer 11

pH-independent. Almost always used by enveloped viruses. Fusion glycoprotein in the envelope of the virus causes release of nucleic acid into the cell from the cell surface without the use of endosomes

Question 12

What is early transcription?

Answer 12

transcription that occurs before genome replication and the point is to transcribe proteins that produce non-structural proteins (i.e. proteins needed for genome replication)

Question 13

Where do RNA encoded viruses replicate?

Answer 13

the cytoplasms because they don’t need much from the nucleus

Question 14

Where do DNA encoded viruses replicate?

Answer 14

the nucleus (with some exceptions)

Question 15

What is late transcription?

Answer 15

transcription of structural proteins after genome replication Naked viruses will then lyse the cell to be released. Enveloped viruses will likely bud from the cellular membrane which forms around it (so it derived from the host cell)Remember: naked viruses will lyse the cell to leave

Question 16

What is the eclipse period of viruses?

Answer 16

only occurs in viruses, not intracellular bacteria. From 2-10 hours at the start of viral infection where a virus cannot be detected inside or outside the cell.At 2 hours all the virus has entered the cell and uncoated so that intracellularly we can’t detect the viral presence. At 10 hours after genome replication (at about 8 hrs) viruses produce/assemble the intracellular progeny virus and we can detect it.

Question 17

When can viruses be detected extracellularly?

Answer 17

about 16 hrs when the progeny are released (the end of the latent period)Latent period= time where viruses can’t be detected extracellularly

Question 18

T or F. RNA viruses must encode their own RNA-dependent RNA polymerase

Answer 18

T. Because the template they are providing is RNA and we use a DNA template

Question 19

Retroviruses must encode what?

Answer 19

reverse transcriptase (think HIV)

Question 20

What is the difference between small and large DNA viruses in terms of DNA polymerase?

Answer 20

Small DNA viruses (HPV )do not have their own DNA polymerase because they are too small and can’t encode them so they use proteins that alter our DNA polymerase for their own use, while large DNA viruses (herpes) can encode their own (we can target these)

Question 21

How does +ssRNA replication occur?

Answer 21

A ribosome will enter the genome via a ribosomal entry site at the 5’ end and translate (TRANSLATION FIRST) a protein that is a polyprotein containing capsid and pol. Then cleavage occurs on the polypeptide (sometimes the protease is virally encoded and sometimes from the host cell). The cleaved polymerase molecule will then recognize the viral genome as a template for the production of additional strands of 3’-5’ RNA (complementary to viral genome) and then that strand can be used to make many (+) 5’-3’ RNA progeny strands. Some of those stands will become messenger RNA for continued translation of proteins to make capsid proteins that will come together to form nucleocapsids that may or may not be enveloped

Question 22

How does -ssRNA replication occur?

Answer 22

The RNA-dependent RNA polymerase (can’t encode inside the cell) must come in with the virus to allow synthesis *(TRANSCRIPTION)** of a + strand of viral genome which will serve as mRNA, then translation occurs resulting in individual proteins (not a polypeptide). This allows for production of more RNA-dependent RNA polymerase to make more - strand progenies and additional mRNA for more protein production. Mature progeny needs negative genome, proteins, AND an RNA polymerase

Question 23

How does retrovirus production occur?

Answer 23

these are positive sense single stranded RNA viruses that must bring in their own reverse transcriptase. Reverse transcriptase synthesizes a complimentary DNA strand, gets rid of the original strand, and synthesizes a second DNA strand to make double stranded molecules that integrate into our chromosome to be transcribed by our host RNA polymerase

Question 24

How is viral growth measured?

Answer 24

Via plaque assays that measure the “hole” in a confluent monolayer of cells that is left after cell lysis. Cell death grows circularly and can be measured this way measured as plaque-forming units (pfu)/ml of lysate= titer This is a biological assay of infectivity. Only get a plaque if the viral particle is infectious. Not all viruses are infectious.

Question 25

What is lysate?

Answer 25

a suspension of visions in culture medium that results from unrestricted growth of the virus on a cell monolayer. As more plaques form, they will grow together and we can a suspension of the virus

Question 26

What is Particle-to-PFU ratio?

Answer 26

number of particles released to the number of those that a re plaque forming. Animal cells have ratios of 10:1

Question 27

T or F. Viral mutations occur at a relatively high frequency.

Answer 27

T. because there are a large number of genome copies and also because of high error rate among RNA polymerase without proof reading ability

Question 28

What is Complementation?

Answer 28

can occur in an RNA or DNA virus. Sharing of proteins among infecting viruses that can allow a viral particle with defective proteins to be integrated by using a protein on another virus simultaneously infecting the host cell. Doesn’t genetically fix the defective protein like recombination does.

Question 29

What is Recombination?

Answer 29

Exchange of DNA material among viruses that are co-infecting a cell which could result in repair of defective proteins on one or both of the viruses. DNA viruses only (although RNA viruses can do ‘strand transfer” which is similar)

Question 30

What is Reassortment?

Answer 30

Limited to RNA segmented viruses. Co-infection of segments of these viruses can result in recombination. Major role in flu virology.

Question 31

What is the most frequent route of infection for viruses?

Answer 31

respiratory. Dissemination is via blood, lymph, CSF, and neurons

Question 32

How does localized cell-to cell spread occur uniquely?

Answer 32

Can occur uniquely: When enveloped viruses bud through a membrane they acquire glycoproteins. Herpes viruses and others (respiratory sensitial) can put a fusionogenic proteins that functions in a pH-independent manner on the host cell membrane that allows them to fuse to adjacent cells (called sensitia formation- HIV can do this too). Direct fusion without release of virus and re-infection of another cellthink gp120 binding to CD4 on HIV

Question 33

T or F. Most viral infections completely resolve without virus-specific treatment.

Answer 33

T. Persistent infections are key for some diseases, especially in immune deficiency

Question 34

What are some types of persistent viral infections?

Answer 34

1) Chronic (productive), eg hep B or C- equilibrium reached with our immune system and not leading to significant stress in a person2) Latent, eg herpes- certain time when the virus cannot be detected because it is not reproducing but is always present in host cell genomes and can come back under stress 3) Transforming, eg papiloma- cancer causing

Question 35

Immune response of viruses

Answer 35

Many of the symptoms seen from viruses are the result of our own bodies attempt to resolve the infection. Our body uses the IFN-alpha pathway

Question 36

Describe the IFN pathway

Answer 36

A cell has bound IFN from a virally infected cell. When binding occurs, the IFN pathway is induced. Study pathway. The pKR and 2-5A synthatase pathways are only FULLY activated by viral double-stranded RNA in that cell. Keeps the cell from killing itself when not infectedPKR pathway shuts down ALL protein synthesis (host and viral) and 2-5A syntheses cleaves ALL RNA in the cell, so a fully activated IFN pathway response will kill the cell to limit the infectionThese pathways help limit the spread of the viral infection

Question 37

Vaccines

Answer 37

Not practical if a large number of strains cause a disease or if a virus exhibits variation in a dominant antigenic structure (e.g. hep C where a 30 AA stretch can mutate to avoid our antibody response so we have to constantly adapt to control it)

Question 38

What are the types of vaccines?

Answer 38

killed, live attenuated, and other subunits

Question 39

Advantages of live vaccines?

Answer 39

can give orally (vs. injecting in killed), dose can be lower, often only one dosing needed (killed need boosters), immunity lasts longer, can get a IgA response (killed only get an IgG response so they don’t inhibit the SPREAD of disease if you poop out the bug)

Question 40

Disadvantages of live vaccines?

Answer 40

heat labile, can become virulent on occasion and cause disease

Question 41

Subunit vaccines?

Answer 41

viral proteins purified for use in papiloma (HPV) and hepatitis (HBV) vaccination. cannot cause disease, not derived from blood, but do require multiple injections to boost immune response

Question 42

What are some live vaccines?

Answer 42

Polio (oral), measles, mumps, rubella, varicella-zoster (chickenpox-shingles), influenza (inhaled), small pox

Question 43

What are some killed vaccines?

Answer 43

Polio (injected), influenza (injected), Hep A, rabies

Question 44

What are some subunit (yeast-derived) vaccines?

Answer 44

Hep B and HPV (can be considered anticancer vaccines)

Question 45

What is the basis of passive vaccination?

Answer 45

Can give immune globulin to protect people immediately so immune response does have to be formed in case of pre- and post- exposure prophylaxis Post-exposure uses include: Hep A or B, measles, rabies, chickenpox

Question 46

What are some of the consequences of enveloped viruses vs. non-enveloped ones?

Answer 46

Envelops are made of lipids that are less stable than the capsids of non-enveloped viruses so they are more sensitive to detergents, heat, and the acidity of the GI tract (so if you see GI distress caused by virus, you know its not an enveloped virus)Spread through droplets, secretions, blood transfusions, lymphThey do help disguise the virus from the host because the sugars on the glycoproteins are from the host.

Question 47

What are prions?

Answer 47

infectious proteins

Question 48

Why do viruses use repeating subunits (capsomeres) to build their capsids?

Answer 48

This allows them to maintain a small genome

Question 49

What must almost every RNA virus encode to replicate its genome?

Answer 49

RNA-dependent RNA polymeraseretroviruses need reverse transcriptase

Question 50

Why can we target nucleoside inhibitors for herpes and not for HPV?

Answer 50

Herpes virus is large enough to encode its own DNA polymerase while HPV is too small and has to use/alters ours so it’d be toxic to target it

Question 51

T or F. DNA viruses use host RNA polymerase II transcribing viral genes.

Answer 51

T. They modify it for preferential use