Lecture 3 banfield

Question 1

what is an eclipse period

Answer 1

time between absorption of a virus to the cell and the appearance of infectious virus

Question 2

what is a latent period

Answer 2

time between absorption of a virus and the release of new infectious virus from the cell

Question 3

can latent period = eclipse period?

Answer 3

yes

Question 4

what period typically ends first? latent or eclipse?

Answer 4

eclipse

Question 5

true or false, viruses grow exponentially

Answer 5

false, they are released as single “burst”

Question 6

what do viruses bind to on the outside of the cell? what kind of energy is normally required for this?

Answer 6

1. glycoproteins
2. carbohydrates (on ends of glycoproteins or glycolipids)
   normally this binding is an energy-independent process

Question 7

what is multiple receptor use?

Answer 7

a single virus may bind more than one receptor on the cell surface (e.g. co-receptors)

Question 8

what are the two penetration processes for viruses after attachment?

Answer 8

1. endocytosis into intracellular vesicles called endosomes

2. fusion of the virus envelope with the cell membrane

Question 9

t or f, unlike attachment, viral penetration requires energy and therefore the cell must be metabolically active

Answer 9

true

Question 10

explain general fusion of viruses to cells (penetration)

Answer 10

• only viruses with envelopes can do this
• requires the presence of a specific fusion protein in the virus envelope!
• requires energy

Question 11

explain pH and virus fusion

Answer 11

virus fusion can be pH dependent (requires acidic endosome) or pH independent where it can occur at the cell surface or in an endosome

Question 12

what kind of receptors aren’t typically virus specific

Answer 12

carbohydrates are less specific then protein receptors

Question 13

what is fuzeon?

Answer 13

a antiviral drug that prevent HIV fusion (site of action of many drugs_

Question 14

what is uncoating?

Answer 14

general term for what occurs after penetration; the capsid is fully or partially removed and allows viral genome to be exposed.

Question 15

explain uncoating that occurs at the plasma membrane

Answer 15

viral membrane fuses at the cell membrane and releases capsid directly into the cytoplasm (the viral envelope becomes integrated into the PM).

Question 16

explain uncoating within an endosome

Answer 16

rather than the virus “fusing” with the membrane it is engulfed by it and forms an endosome. This endosmoe then expels the capsid. low pH facilitates the endosome releasing the capsid

Question 17

explain uncoating at the nuclear membrane.

Answer 17

virus is engulfed into an endosome into the cell. the endosome lyses before the nucleus where it docks the nuclear membrane. the viral genome is feed into the nucleus while the capsid is degraded / remains outside

Question 18

explain the general process of a virus that attaches a cell, then penetrates via endocytosis and then un-coats at the nuclear membrane (6)

Answer 18

1. binds carb or protein receptor
2. is engulfed into an endosome
3. acidic endosome begins to break down viral proteins
4. acid-dependent endosome lysis occurs
5. capsid uses microtubule transport to nucleus
6. capsid binds and un-coating occurs. this allows viral genome to enter nucleus

Question 19

what is the meaning of polarized microtubules?

Answer 19

microtubules allow larger component to move in the cell since the cytoplasm is dense. Polarized = (+/-) indicate the direction of movement

Question 20

what kind of transport does herpes virus us use?

Answer 20

binds microtubules on the minus end. once at the nucleus, herpes capsids are packed with a lot of pressure which allows their genome to burst into the nucleus upon un-coating.

Question 21

why does polio virus have a unique un-coating mechanism

Answer 21

polio virus is a non-envelope virus. it does not need to penetrate the cell at all. It simply binds the PM and injects its genome directly into the cytoplasm

Question 22

How do most DNA viruses express their genomes?

Answer 22

they must use their - sense strand to produce mRNA (+). this transcription is done by RNA polymerase 2. which is located in the nucleus or brought with the virus (pox virus)

Question 23

How would a + strand RNA virus express its genome?

Answer 23

these are already + strand mRNA!! they are directly translated
(retro virus is an exception that does not do this)

Question 24

retroviruses are + strand RNA viruses but they do not immediately translate? what do they do?

Answer 24

they turn their +RNA to -DNA. then -DNA to dsDNA. this can incorporate into our genome which is why retroviruses are life long. . This dsDNA is transcribed by the -strand into +mRNA.

Question 25

how do -RNA and dsRNA express their genome?

Answer 25

+mRNA must be made. To do this these enzymes use RNA-dependent RNA polymerase. Animal cells DO NOT contain these enzymes. therefore, -RNA and dsRNA MUST BRING IT WITH THEM.

Question 26

what RNA viruses are known to replicate through a DNA intermediate?

Answer 26

retroviruses

+RNA –> -DNA –> dsDNA –> +mRNA

Question 27

how do retroviruses make DNA from RNA?

Answer 27

they bring with them a reverse transcriptase enzyme.

Question 28

what is a provirus?

Answer 28

once a viruses genome integrates into the host genome it is called a provirus. Retroviruses use reverse transcriptase to make dsDNA. This integrates to form a provirus. RNA pol 2 then makes +mRNA.

Question 29

genome replication: ds DNA viruses (2 types)

Answer 29

1. exclusively nuclear and uses cellular machinery

2. cytoplasmic (independent of cell machinery usually)

Question 30

Genome replication: ssDNA

Answer 30

occurs in nucleus where dsDNA intermediate is made first. thsis acts as a template to make multiple ssDNA.

Question 31

why do small DNA viruses often cause cancer?

Answer 31

they push cells into the cell cycle which increases the number of RNA polymerases which can lead to cell proliferation

Question 32

where do most RNA viruses replicate. What is the exception

Answer 32

RNA viruses typically replicate in the cytoplasm. Orthomyxoviruses are the exception

Question 33

how does +RNA viruses typically replicate

Answer 33

they immediately get translated into multiple proteins. One of these proteins will be an RNA-dependent RNA polymerase which will transcribe the +RNA into -RNA. this serves as a template for replication.

Question 34

there are two forms of +RNA replication. what are they?

Answer 34

1. +RNA translates into a polyprotein that cleaves off into smaller ones. One of them transcribes the +RNA.
2. +RNA is transcribed into -RNA. this creates subgenomic +mRNA’s which encode protein.

Question 35

what is the genome replication / expression for segmented

-RNA viruses

Answer 35

segmented RNA viruses –> the -RNA is used as a template to make mRNA. It is also used to replicate the whole genome into a +RNA. this is used as a template to make more -RNA.
the segmented mRNA that is made codes for 1 protein per segment

Question 36

what is the genome replication / expression for non-segmented -RNA viruses

Answer 36

non-segmented
-RNA viruses have one long piece of RNA. RNA dependent RNA polymerase synthesizes a bunch of subgenomic +mRNA molecules. each one makes a protein. the -strand is also turned into a + strand for replication

Question 37

what is the key difference between segmented and uni-molecular -RNA virus expression and replication?

Answer 37

uni - molecular –> one long - sense RNA which produces many subgenomic mRNA molecules to be transcribed into proteins (RNA-dependent RNA pol). it is also transcribed lengthwise for genome replication.

segmented –> The actual - RNA genome has multiple pieces, each codes for a protein (mRNA) and codes for a replicative transcript)

Question 38

what is the GP / NP small RNA?

Answer 38

an ambisense RNA

Question 39

how do GP/NP viruses work?

Answer 39

these are ambiviruses.

1) The - strand NP section gets transcribed into mRNA which is translated into a protein
2) replication of the RNA occurs which switches its polarity
3) now the GP region is transcribed and translated

Question 40

how do dsRNA viruses replicate and express?

Answer 40

the -RNA is synthesized into +RNA to be translated. another +RNA is made to be replicated. RNA-dependent RNA pol performs this.

Question 41

how does the virus ensure that only +mRNA is translated and not the + strand full-length complement too?

Answer 41

the mRNA in most viruses has a 5’ cap which initiates translation. The full complement +strand used for replication does not contain this .

Question 42

why do some viruses perform their replication in cell membrane?

Answer 42

they avoid the cell immune response from recognizing ds intermediates.

Question 43

what is virus assembly?

Answer 43

packaging of the genome into the capsid made by translated proteins

Question 44

what are the two ways assembly can occur with icosahedral capsids?

Answer 44

1. the capsid is formed around the viral genome. (not well understood)
2. the viral genome is fed into the pre-made capsid

Question 45

how does helical nucleocapsids assemble?

Answer 45

recall: helical capsids always have RNA genomes. the RNA genome is coated with nucleocapsid protein during synthesis which causes folding.

Question 46

what has 20 faces and 12 vertices?

Answer 46

icosahedral capsids. the vertices are either pentamers or hexamers (where the faces all meet)

Question 47

what are VP5 proteins and UL6?.

Answer 47

VP5 are the proteins that make up 11 hex and pent verticies of the Herpes (icosahedral) capsid. The UL6 protein is a portal which makes up the last verticie

Question 48

what is a pro-capsid?

Answer 48

capsid made before genome is added. Typically filled with scaffolding proteins

Question 49

explain the general herpes virus assembly progress

Answer 49

the translation of herpes genome creates many proteins. the first protein of the capsid is UL6 portal. then VP5 assembles the pent and hex vertices around this. a protease chews up scaffold proteins and permits herpes replicated genome to be fed into the capsid through UL6.

Question 50

what are inclusions?

Answer 50

a cytopathic effect (CPE) in which so many viral capsid proteins are made they form small clusters (inclusions) in the cytoplasm or nucleus.

Question 51

why are inclusions important?

Answer 51

the size and location of them are very characteristic pf different viruses.

Question 52

where are the inclusions found for herpes virus?

Answer 52

inside the nucleus

Question 53

what is egress?

Answer 53

exit of the virus from the cell

Question 54

how does naked virus egress occur?

Answer 54

poorly understood. Essentially the virus releases viroporins which disrupt the cell membrane and cause lysis. This permits exit of the virus and kills the cell.

Question 55

how do enveloped viruses egress?

Answer 55

through a process called budding –> they acquire an envelope from a variety of cellular membranes

Question 56

explain the two common budding envelopes

Answer 56

1. viruses can bud with the PM and then be released directly
2. viruses can bud with the golgi or the ER and then be secreted by the cell.

Question 57

explain the general process of herpes virus egress.

Answer 57

1. nucleocapsid leaves nucleus by forming an endosome
2. they then leave the perinuclear space by fusing with the perinuclear membrane.
3. they then bud
   enter golgi by making an endosome. (acquired envelope)
4. they then leave golgi b acquiring an outer membrane (nucleosome around a nucleosome)
5. they then fuse their outer membrane with the PM and leave keeping their golgi body membrane

Question 58

when is the herpes virus considered infectious?

Answer 58

once it is delivered to the golgi body.

Question 59

how does HIV budding occur? why does this increase infectivity

Answer 59

budding occurs via cell to cell contact of T-cells. infectivity increases since upon budding the virus is directly transferred.

Question 60

how can some viruses transmit their newly formed virus directly from one cell to another?

Answer 60

the virus forms an envelope through budding. this gets modified to contain an actin tail. The exocytosis of the enveloped virus is then pushed by the actin tail directly into adjacent cells.