Chapter 9 - Bacterial and Viral Genetic Systems

Question 1

What are some examples of important contributions bacteria and viruses have made to genetics?

Answer 1

• Evidence for nature of genetic material (DNA)
• First characteristics/definitions of gene
• First evidence for gene interactions at molecular level
• Basic principles of inheritance

Question 2

What makes bacteria valuable research objects?

Answer 2

• Small size
• Rapid reproduction
• Selective media that can easily identify presence of an active allele
• Simple structures/physiology
• Genetic variability

Question 3

What are bacterial viruses/bacteriophages?

Answer 3

• Reproduce by infecting bacterial cells

- Helped discover some important genetic concepts

Question 4

How do bacteria grow in liquid media?

Answer 4

• Inoculate medium with bacteria

- Bacteria grow and divide

Question 5

How do bacteria grow in solid media?

Answer 5

• Growth medium is suspended in gelatin-like agar
• Add a dilute solution of bacteria to petri plate
• Spread evenly with glass rod
• After incubation for 1-2 days, bacteria multiply, forming visible colonies

Question 6

What do bacteriophages produce on plates with dense bacterial cultures?

Answer 6

• Clearances/plaques within hours of infection

Question 7

What does Bacteriophage T4 consist of?

Answer 7

• Protein head
• 168,800 base pairs and 150 characterized genes
• Fairly large/complex genome for a virus
• Phage goes through lytic phase (lyses cell to infect other cells); quick/simple experiments
• No dormant phase
• Tail fibres land and hook onto plasma membrane

Question 8

What does Bacteriophage Lambda consist of?

Answer 8

• 48,502 base pairs and 50 genes (about 1/3 of T4)

- May be lytic or lysogenic (inserts DNA into host and goes into latency/dormancy)

Question 9

How does a retrovirus work?

Answer 9

• Attaches at receptors in membrane
• Viral core enters host
• Viral RNA uses reverse transcriptase to make complementary DNA
• Reverse transcriptase synthesizes 2nd DNA strand
• Viral DNA enters nucleus and is integrated into host chromosome (forming provirus)
• Proviral DNA is transcribed into viral RNA on activation
• RNA is translated in cytoplasm
• Viral RNA, proteins, new capsids and envelopes are assembled
• Assembled virus buds from cell membrane

Question 10

What is the lytic cycle?

Answer 10

• Phage binds to bacterium
• Phage DNA enters host
• Host DNA is digested
• Phage DNA replicates
• Host cell transcribes/translates phage DNA -> proteins, phages are assembled
• Phage encoded enzyme causes cell to lyse
• New phages released to start cycle again

Question 11

What is the lysogenic cycle?

Answer 11

• Phage binds to bacterium
• Phage DNA enters host
• Phage DNA integrates into bacterial chromosome (becomes prophage)
• Prophage is replicated as part of bacterial chromosome (can be many cell divisions)
• Prophage may separate from chromosome and cell will enter lytic cycle after dormancy

Question 12

Why would an infected cell go through dormancy?

Answer 12

• Nutrients are scarce
• Host is sick
• Not happy with conditions

Question 13

What do bacterial genomes look like?

Answer 13

• Circular molecules
• Several million base pairs
• Double-stranded DNA molecule

Question 14

Where is additional genetic material found in bacteria?

Answer 14

• Plasmids (small circular DNA)

- Can replicate independently of bacterial chromosome

Question 15

What are episomes?

Answer 15

• Subclass of plasmid
• Large circular DNA
• Can integrate into bacterial chromosome for replication or remain separate

Question 16

Is bacterial recombination possible?

Answer 16

• Yes, but not through meiosis/mitosis

Question 17

Is gene transfer unidirectional or bidirectional?

Answer 17

• Unidirectional

Question 18

Gene mutations can be readily observed via… (4)

Answer 18

• Colony colour and morphology
• Nutritional mutants (cannot metabolise certain sugars)
• Prototrophs (can make all AAs) and auxotrophs (cannot make certain AAs, need to be added to medium)
• Antibiotic resistance

Question 19

What happens when a bacterial culture is plated onto petri dishes containing and lacking leucine? Why is this useful?

Answer 19

LACKING
- Only leu+ grow
CONTAINING
- leu+ and leu- grow

• Leucine auxotrophs (leu-) are recovered and cultured for further study
• A colony that grows only on supplemented medium has a mutation in gene that encodes synthesis of essential nutrient

Question 20

What are the 3 parasexual processes through which bacteria exchange genetic material?

Answer 20

• Conjugation
• Transformation
• Transduction

Question 21

What happens in conjugation?

Answer 21

• Direct transfer of DNA from one cell to another via cytoplasmic bridge
• ‘sexual’ reproduction mediated by Fertility/F factor (an episome)
• Cytoplasmic bridge forms b/n bacteria cells
• DNA replicates and transfers from one cell to another
• Transferred DNA replicates
• A crossover in the recipient cell leads to the creation of a recombinant chromosome
• Cell contact IS required
• It is NOT sensitive to DNase

Question 22

What happens in transformation?

Answer 22

• Transfer of free piece of DNA from one bacterium into another
• Competent bacterial cells take up DNA from environment
• Transferred DNA can be stably inherited
• Naked DNA is taken up by recipient cell
• Crossover in bacterium leads to recombinant chromosome
• Cell contact is NOT required
• It IS sensitive to DNase

Question 23

What happens in transduction?

Answer 23

• Transfer of genes from one cell to another via bacteriophage
• Bacteriophage can ‘hijack’ bacterial chromosome genes during phage assembly and donate hijacked genes to another cell
• Virus attaches to bacterial cell, injects its DNA and replicates (taking up bacterial DNA)
• Cell lyses
• Virus infects new bacterium carrying bacterial DNA with it
• Crossover in recipient leads to recombinant chromosome
• Cell contact is NOT required
• It is NOT sensitive to DNase
• Transfer of genes from donor strain and recombination produce transductants in recipient bacteria

Question 24

How do we establish the need for contact?

Answer 24

• U-tube experiment
• 2 auxotrophic strains were separated by filter
• No prototrophic bacteria were produced
• Therefore genetic exchange requires direct contact b/n bacterial cells

Question 25

What is a competent bacterium?

Answer 25

• Can bind exogenous DNA and transport it into the cell

Question 26

What can transformation be used for?

Answer 26

• To determine distance b/n genes
• Only 0.2-0.5% of chromosome undergoes transformation
• If 2 genes are close, they will be present on same piece of DNA
• Transformation is measured as a change in phenotype and it occurs with a certain frequency

Question 27

How is the rate of cotransformation related to distance between genes?

Answer 27

Rate of cotransformation is inversely proportional to distance between genes
- As distance increases, cotransformation decreases

Question 28

How can an F-factor exist?

Answer 28

• As extra-chromosomal DNA
  OR
• Insert into the bacterial chromosome and replicate as part of it

Question 29

What is a F- cell?

Answer 29

No F factor

Question 30

What is a F+ cell?

Answer 30

Autonomous F factor

Question 31

What is a Hfr cell?

Answer 31

Integrated F factor

Question 32

What is conjugation in E. coli mediated by?

Answer 32

Cytoplasmic ‘conjugation’ channel

Question 33

What happens in a F+ x F- cross?

Answer 33

• F pili of F+ make contact with F- to pull cells together
• Genes on F factor direct synthesis of conjugation bridge
• One strand of DNA is cleaved at origin of F factor
• Rolling-circle replication transfers one strand into F-
• Replication occurs in both cells during transfer
• Ends with 2 F+ bacteria

Question 34

What happens in a Hfr x F- cross?

Answer 34

• F is nicked and 5’ end moves into F- cell
• Transferred strand replicates and crossing over takes place b/n donated Hfr and original F- chromosome
• Crossing over may lead to recombination
• Linear chromosome is degraded

Question 35

What happens in Hfr1?

Answer 35

• F is integrated b/n leu gene and azi gene

- So the genes are transferred beginning with leu

Question 36

What happens in Hfr5?

Answer 36

• F is integrated b/n thi and his

- F has the opposite orientation in this chromosome, so the genes are transferred beginning with thi

Question 37

Conjugation b/n an F+ and F- cell usually results in what?

Answer 37

2 F+ cells

Question 38

What is a plasmid?

Answer 38

• An extra-chromosomal circular piece of DNA
• Can replicate independently of chromosome
• In general, not required for survival of host cell and serve as auxiliary genetic elements

Question 39

What is an episome?

Answer 39

• Genetic element that is not essential to the host and that can either replicate autonomously or be integrated into the bacterial chromosome

Question 40

What are examples of plasmids and episomes in E. coli?

Answer 40

• F factor (episome; fertility factor)

- R plasmids (resistance plasmids)

Question 41

How are distance between genes and cotransduction related?

Answer 41

• Genes close to one another are more likely to be cotransduced
• Rate of cotransduction is inversely proportional to distance b/n genes