2-19 Viral Genetics

Question 1

How do viruses encode their genomes?

Answer 1

• DNA or RNA but not both
• Single- or double-stranded
• Linear or circular
• One segment or multiple segments

Viruses have from 2 genes (as in parvoviruses) to 200 genes (as in pox viruses). This is too few for independent survival, and viruses depend on cellular genes to supply the missing functions.

Question 2

How do viruses express genes?

Answer 2

As with bacteria or humans: genes = enhancer/promoter region + ribosomal entry site + open reading frame.

UNLIKE bacteria:

• No operons
• Expression is not induced by interaction between an operator and a repressor/inducer, but by binding of cellular transcription factors to promoter regions (thus, viruses are eukaryotic)

Question 3

What kinds of viral genome structures are there?

Answer 3

• Simple genomes: Genes in a linear arrangement on one RNA strand, with only a single promoter (e.g., retroviruses)
• Complex genomes: Genes on both strands of DNA, often overlapping, and each with its own promoter (e.g., adenoviruses, herpesviruses, poxviruses)

Question 4

How do viruses compress their functions into minimal space for maximal efficiency?

Answer 4

• No non-coding regions
• Overlapping reading frames
• Translational frameshifts
• Splices
• Polyproteins, which are cleaved into individual proteins by specific proteases, which makes 1 promoter enough for an entire virus. (These proteases are unique to viruses and, therefore, potential drug targets, especially for HIV and hepatitis C.)

Question 5

How common is viral mutation, and why?

Answer 5

Mutation frequency is high:

• High error rate of polymerase
• Lack of proofreading and error correction
• Lack of second strand in some viruses
• Small amount of genetic material, with no “waste”

DNA viruses are fairly stable, while RNA viruses are very unstable (1 mutation per generation).

Question 6

Why are mutations important in viruses?

Answer 6

• Allow epidemiological studies (e.g., MERS)
• Allow live vaccines to be made (e.g., early polio vaccine; some mutations only allow a virus to grow under certain conditions)
• Can produce new antigens which avoid immunity (e.g. influenza antigenic drift)
• Can lead to drug resistance (e.g., protease of Hepatitis C)
• Integration of viral genome can cause disease (e.g., papillomavirus in cervical cancer)

Question 7

What can happen if two viruses infect one cell?

Answer 7

The infection of 2 viruses in 1 cell is uncommon, because one will usually preclude the other, but when it happens, 1 of 4 things may follow:

1. Complementation of 2 defective viruses: neither can produce progeny virus alone, but together they can produce viable progeny virus A and viable progeny virus B
2. Phenotypic mixing of similar viruses: 2 very similar viruses will produce progeny for virus A and B, but also some pseudotypes via exchange of capsid proteins (virus A w/ B characteristics, virus B w/ A characteristics), which only last 1 generation
3. Recombination of homologous viruses: 2 homologues enter a cell and cross over during replication, producing progeny different from parents
4. Reassortment of segmented viral genomes: 2 segmented viruses mix segments, producing progeny different from parents

Question 8

Why are most cells/organisms only infected with one virus at a time (i.e., why is viral interaction rare)?

Answer 8

• Blocking of receptors
• Competition for resources
• Stimulation of innate immunity

Question 9

How would viruses be used in gene therapy?

Answer 9

• Delete an essential gene from virus
• Insert that gene into ‘complementing’ cell
• Clone the therapeutic human gene into virus
• Grow the virus in the complementing cell
• Test virus in cells, animals, humans

Diseases that might be treated by gene therapy are mainly those with a congenital lack of a single gene/protein (e.g., CF, combined immunodeficiency, hemophilia, various liver enzyme-deficiency disorders).

Delivery of gene therapy by viruses involves host-range mutants, which can be made from retroviruses, adenoviruses, herpes simplex virus, and adeno-associated virus.

Question 10

What are some problems associated with viral gene therapy?

Answer 10

• Short duration of expression
• Very high doses of viral vectors required (low efficiency of gene transfer)
• Severe inflammation in response to the virus
• Insertion of viruses into a recipient’s genome leading to malignant disease