Topic 1

Question 1

Humans have __ pair(s) of autosomes and __ pair(s) of sex chromosomes

Answer 1

22 pairs of autosomes, 1 pair of sex chromosomes

Question 2

What two sets of genomes do humans have?

Answer 2

The mitochondrial genome and the nuclear genome

Question 3

How many mtDNA genes? Approximately how many nucleotides?

Answer 3

37 genes, approximately 16.6 kb

Question 4

How many rRNA coding mtDNA genes?

Answer 4

2

Question 5

How many tRNA coding mtDNA genes?

Answer 5

22

Question 6

How many polypeptide coding mtDNA genes?

Answer 6

13

Question 7

Approximately how many genes in nuclear chromosomes?

Answer 7

3.2 x 10^9

Question 8

How do X and Y chromosomes differ?

Answer 8

• They are structurally distinct and are subject to different forms of genetics regulation.
• They also have their own patterns of inheritance (e.g. Y can only come from the father)

Question 9

Females have 2 times more X-linked gene expression than males. How is this dosage imbalance corrected?

Answer 9

Through dosage compensation
- through inactivation of one of the X chromosomes in females.

Question 10

What is the X chromosome inactivation theory?

Answer 10

In the somatic cells of normal females (but not males), one of the two X chromosomes is randomly inactivated early in development.

Question 11

True or false: The inactivated X chromosome remains inactive for the rest of the female’s life

Answer 11

False
- The inactivated X chromosome becomes reactivated in oogenesis in the germ line

Question 12

How was X chromosome inactivation initially identified?

Answer 12

X chromosome inactivation was initially identified through the discovery of a highly condense, heterochromatic structure called the Barr body in interphase cells.

Question 13

Describe how X chromosomes are inactivated

Answer 13

On the X chromosome, there is a region called the X inactivating center (XIC). This region can be decorated with XIST RNA, which changes the morphology of the X chromosome and therefore decreases expression of genes in the X-linked gene.

Question 14

How can scientists determine the function of XIST?

Answer 14

rBy doing a knockout with siRNA, CRISPR or site-directed mutagenesis. Can the use the Northern blot of qPCR to quantify RNA content after knockout.

Question 15

What is Klinefelter syndrome?

Answer 15

• When a male has a 47, XXY trisomy.
• One of the X chromosomes will become inactivated like in females, but some genes on the “inactive” X chromosome escape X inactivation.

Question 16

What are some of the symptoms of Klinefelter syndrome?

Answer 16

• infertility
• tall/thin with long legs (decreased muscle tone)
• hypogonadism (low testosterone)
• underdeveloped secondary sexual characteristics.

Question 17

In Klinefelter syndrome, why do individuals with the genotypes 48 XXXY and 49 XXXXY have more severe phenotypes?

Answer 17

Because there’s more X leakage

Question 18

Bacteriophage

Answer 18

Virus that infects bacteria

Question 19

Lambda (λ) phage

Answer 19

DNA virus that infects the bacterial species, such as E.coli

Question 20

How many bps in λ chromosome? How many genes?

Answer 20

~48,500 bp, ~50 genes

Question 21

The λ coat contains how many proteins (from head to tail)?

Answer 21

~15

Question 22

Prophage

Answer 22

A phage DNA (in its dormant state) that integrates into the bacterial chromosome

Question 23

Lysogen

Answer 23

The bacterial cell that harbors the prophage

Question 24

Lytic cycle

Answer 24

After bacteriophage injects DNA, DNA replicates and proteins are transcribed in bacteria, more bacteriophages produced in bacteria and then host lyses.
- kills host cell

Question 25

Lysogenic cycle

Answer 25

Prophage is integrated into bacterial chromosome. Host is not lysed.

Question 26

What happens if lysogen undergoes UV induction?

Answer 26

Lytic cycle is induced

Question 27

On a plaque assay, if there’s more spots that means…

Answer 27

There are more bacteriophages

Question 28

On a plaque assay, if there’s more clear plaques…

Answer 28

There is more lytic growth

Question 29

On a plaque assay, if there’s more cloudy (turbid) plaques…

Answer 29

There is more lysogenic growth

Question 30

If there is full growth on a plaque assay (no spots), this indicates that…

Answer 30

Cells are not being lysed

Question 31

Explain the immunity of the λ-lysogen

Answer 31

Repressor molecules maintain the prophage in its dormant state. These repressor molecules prevent further λ infection and lysis.
- When the λ repressor protein (aka cI) is predominant, λ phage enters the lysogenic pathway (its DNA integrates into the host chromosome, and only the λ repressor itself is expressed)

Question 32

Explain the effect of UV on the λ repressors

Answer 32

UV inactivates these repressors, so then another regulatory protein called Cro becomes predominant. When this protein is predominant, λ phage enters the lytic cycle (most of the λ genes are expressed, and viral replication/packaging ensue.

Question 33

Cro protein general function

Answer 33

Control of repressor and other genes

Question 34

cII protein

Answer 34

The cII protein is a transcription activator that enhances transcription of the λ repressor gene and hence stimulates production of the repressor protein (cI). When cII is abundant and active, infection proceeds through the lysogenic pathway.

Question 35

Cro gene and cI (λ) gene status in lytic cycle

Answer 35

• Cro gene is on
• cI (λ) repressor gene is off

Question 36

Cro gene and cI (λ) gene status in lysogenic cycle

Answer 36

• Cro gene is off
• cI (λ) repressor gene is on

Question 37

Order of λ control regions (promoters) and genes from left to right on chromosome

Answer 37

PL, cI gene, PRM, PR, cro gene

Question 38

In lytic cycle, describe the PL, PRM and PR promoter statuses

Answer 38

PL is on, PRM is off, PR is on.
- Results in no cI being expressed, but cro is expresssed (PR is cro promoter)
- N protein (gene that PL promotes) is also expressed.

Question 39

In lysogenic cycle, describe the PL, PRM and PR promoter statuses

Answer 39

Only PRM is on, so cI is expressed but cro is not expressed

Question 40

Operator general function

Answer 40

A DNA sequence that can be recognized and bound by a repressor protein to block transcription of the gene.

Question 41

Promoter general function

Answer 41

DNA sequence that can be recognized and bound by an RNA polymerase to initiate transcription of the gene.

Question 42

How many operators are there between the PRM and PR promoters?

Answer 42

3, from left to right: OR3, OR2, OR1

Question 43

True or false: the RNA polymerase that transcribes the cro or cI gene in the bacteriophage comes from the virus

Answer 43

False. The RNA pol comes from the host.

Question 44

The PRM promoter transcribes the ___ gene, and activator proteins (are/are not) required for transcription initiation

Answer 44

The PRM promoter transcribes the cI gene, and activator proteins are required for transcription initiation

Question 45

Describe the structure of the cI (λ) repressor, in terms of amino acids and domains

Answer 45

• 236 amino acids in length (25,960 Da)
• 2 domains (N/amino domain and C/carboxyl domain)
• Attached by a 40 amino acid linker

Question 46

The PR promoter transcribes the ___ gene, and activator proteins (are/are not) required for transcription initiation

Answer 46

The PR promoter transcribes the cro gene, and activator proteins are not required for transcription initiation

Question 47

What are the 4 subdomains and their locations on the cI repressor?

Answer 47

C domain:
- tetramerization domain
- dimerization domain
N domain:
- activating region
- DNA binding domain

Question 48

Can the λ repressor bind to the prophage operator as a monomer?

Answer 48

No; the repressor can associate with itself to form a homodimer. Only the dimers can cooperatively bind to the operators via their amino domains.

Question 49

How many amino acids in Cro protein?

Answer 49

66

Question 50

Cro monomers have (very high/very low) affinity for each other, which results in…

Answer 50

Cro monomers have very high affinity for each other and are almost always forming dimers

Question 51

True or false: Cro binds the same operators as the cI repressor

Answer 51

True, but they play an opposing role because Cro promotes the lytic cycle instead.

Question 52

What lab technique could you use study the binding interactions between the phage DNA and the DNA+ Cro protein?

Answer 52

• electrophoretic mobility shift assay (EMSA)
• basically just gel electrophoresis with two lanes, one lane is DNA and the other lane is DNA + protein. If protein bind to the DNA, then the fragment in this lane travels slower.

Question 53

Which one of the following statements is false regarding the role of the λ repressor in regulation of phage transcription?
a) λ repressor bound to DNA excludes RNA polymerase
b) λ repressor cooperatively binds DNA
c) λ repressor lacks an activation domain
d) λ repressor recruits RNA polymerase to the promoter

Answer 53

c

Question 54

If the cellular concentration of a repressor protein is several orders of magnitude greater than the dissociation constant for the repressor-operator complex, how often will the operator be bound by repressor?

Answer 54

The operator site will almost always be bound by repressor.

Question 55

Describe what happens to the cI gene if the cI repressor binds at OR2

Answer 55

cI positively regulated the expression of its own gene by enhancing the binding of RNA polymerase to PRM

Question 56

Describe what happens to the cro gene if the cI repressor binds at OR2

Answer 56

cI physically blocks RNA polymerase from binding the PR promoter and suppresses the transcription of the cro gene
- Is an example of the principle of exclusion, which is a very common mechanism of gene regulation

Question 57

Describe what happens to the cI and cro genes when the cI repressor binds to OR3

Answer 57

• Negatively regulates the cI transcription by preventing RNA polymerase from binding at the PRM promoter
• No effect on PR: cro gene is on (lytic cycle activated)

Question 58

Describe what happens to the cI and cro genes when the lambda repressor binds to OR1

Answer 58

• Negatively regulates the cro transcription by blocking RNA polymerase from binding to the PR promoter
• PRM is only weakly activated, because the repressor at OR1 is too far away to affect RNA polymerase

Question 59

In the lysogenic state, >90% of the phages are found with repressors bound to OR1 and OR2 (but not OR3), while <10% of the phages are found with repressors bound to all three operators. What 2 factors affect this?

Answer 59

1. Repressor dimer has an “intrinsic” affinity for each operator site (i.e., OR1 > OR2 > OR3)
2. Interaction of repressor dimer at adjacent sites to facilitate OR binding (cooperativity from OR1/OR2 binding makes repressor lean away from repressor bound to OR2)

Question 60

Given the choice, the repressor will bind to (this operator), but if the concentration of repressor increases, then the repressor will begin to bind at (this operator)

Answer 60

Given the choice, the repressor will bind to OR1, but if the concentration of repressor increases, then the repressor will begin to bind at OR2

Question 61

True or false: When the cI repressor is bound to both OR1 and OR2, these dimers are in physical contact

Answer 61

True

Question 62

Describe the cooperative binding involving the λ repressor

Answer 62

Cooperativity is seen as the binding of repressor at OR1 increases the affinity at OR2 for another repressor dimer

Question 63

True or false: OR3 binding by the λ repressor is also strong

Answer 63

False
- Repressor binds to OR3 much more weakly than OR2 -> requires a much higher [repressor] for OR3 binding

Question 64

Describe why the binding of the λ repressor to OR3 is weak

Answer 64

The repressor dimer at OR2 is unable to interact with a repressor at OR3 (to form a tetramer), because it is already “leaning” towards the dimer at OR1

Question 65

True or false: RNA polymerase needs OR2 repressor bound to be recruited to PRM (only OR1 isn’t enough)

Answer 65

True

Question 66

Describe how UV induces the lytic cycle

Answer 66

1. UV causes DNA damage
2. DNA damage activates the E.coli protein, RecA (a recombinase, promotes recombination during meiosis I and triggers DNA repair by activating protein degradation)
3. RecA induces proteolysis of repressor monomers
4. The split monomers cannot dimerize

Question 67

Describe the SOS response in E.coli (6 steps)

Answer 67

1. UV causes DNA damage
2. Rec A is activated (an E.coli protein)
3. RecA induces proteolysis of Lex A (transcription suppressor on promoter of UvrA, UmuC and UmuD)
4. Transcription of UvrA, UmuC and UmuD is turned on
5. When these genes are on, nucleotide excision repair is activated 6. If nucleotide excision repair doesn’t work, the genes turn on even with the mutation (life or death choice)

Question 68

How does proteolysis reduce [repressor]?

Answer 68

Decreased repressor dimer means decreased dimer bound at OR1 and OR2 so decreased repressor synthesis

Question 69

True or false: Cro dimers bind cooperatively

Answer 69

False
- Cro dimers bind independently to OR sites

Question 70

What lab technique can we use to examine when operator binding is maximized with varying [Cro]?

Answer 70

EMSA

Question 71

What is the affinity of Cro for OR 1-3?

Answer 71

OR3>OR1=OR2
- Almost opposite of the λ repressor

Question 72

When Cro is bound to OR3…

Answer 72

λ expression is turned off because the repressor prevents RNA pol from binding PRM
- Opens up PR to bind RNA pol to express Cro protein

Question 73

λ repressor is said to be both a positive or a negative regulator, while Cro is said to be only a negative regulator. Why?

Answer 73

• λ negatively regulates its own expression when bound to OR3 (which barely ever happens). λ positively regulates its own expression when bound to OR1 and OR2 (it ENHANCES the binding of RNA pol to OR3). λ also negatively regulates Cro expression when bound to OR1 and/or OR2.
• When Cro binds to OR3, it negatively regulates λ expression (and does not enhance RNA binding to PR, just doesn’t block PR) but when it’s bound to OR2/OR1 or all OR sites, it negatively regulates its own expression

Question 74

After the lambda repressor is degraded, the PRM promoter and OR sites are free of any repressor. What happens to PRM over time?

Answer 74

Eventually, the PRM is off.

Question 75

What happens to cI and Cro gene expression when the lambda repressor binds to OR2 only (although this is rare)?

Answer 75

• Repressor physically blocks RNA polymerase from binding the Pr promoter and suppresses the transcription of the Cro gene
• cI gene still transcribed

Question 76

Which gene is turned on when the lambda repressor is bound to OR3 only (even though this is rare due to cooperative binding)?

Answer 76

cI is off, Cro is on

Question 77

What happens when the Cro protein binds to OR3 and OR2?

Answer 77

both cI and Cro are off

Question 78

What happens when the Cro protein binds to OR3 and OR1?

Answer 78

both cI and Cro are off

Question 79

Which of the following occurs more often in cells?
a) Cro binds OR3 and OR2
b) Cro binds OR3 and OR1

Answer 79

Both occur with equal probability because affinity of Cro for OR1 and OR2 are equal

Question 80

PR is a strong promoter. What does this imply about its transcription?

Answer 80

It is always on unless repressed (constitutive)

Question 81

What is the role of lambda repressors for the continuation of the lysogenic cycle?

Answer 81

They maintain the prophage in the dormant state and prevent further phage infection and subsequent lysis by sequestering phages entering the cell

Question 82

True or false: The PRM and PR promoters can be occupied simultaneously

Answer 82

False