Lecture 1 - Exam 2

Question 1

Who discovered DNA? What did he specifically discover?

Answer 1

Friedrich Miescher. He discovered “nuclein” in nuclei of human white blood cells.

Question 2

What are nucleotides in DNA composed of?

Answer 2

1. A phosphate group
2. A pentose sugar (ribose or deoxyribose)
3. A single nitrogen-containing base

Question 3

What are the two basic categories of nitrogenous bases?

Answer 3

Purines: Adenine (A) and Guanine (G)
Pyrimidines: Cytosine (C), Thymine (T), and Uracil (U)

Question 4

What are DNA’s nitrogenous bases?

Answer 4

A, G, C and T

Question 5

What are RNA’s nitrogenous bases?

Answer 5

A, G, C, and U

Question 6

Cytosine can spontaneously deaminate _____? If this base was used routinely in DNA, then could the DNA repair mechanisms detect this spontaneous mutation?

Answer 6

Uracil
No, it couldn’t detect this spontaneous mutation.

Question 7

What allows the repair mechanism in DNA to identify a spontaneous Cytosine to Uracil mutation?

Answer 7

Thymine is (basically) methylated Uracil, so using Thymine in DNA allows the repair mechanism to identify a spontaneous Cytosine to Uracil mutation, and replace U with a C.

Question 8

What is a nucleoside?
Adding what would make it a nucleotide?

Answer 8

A pentose sugar plus nitrogenous base
The addition of a phosphate group to the 5’ C of a nucleoside makes it a nucleotide.

Question 9

________ are joined together to make one of the strands of DNA.

Answer 9

Nucleotides

Question 10

The ______ of one nucleotide can form a bond with the _______ group of another nucleotide. Joined together by __________ bonds.

Answer 10

3’ OH ; 5’ Phosphate ; Phosphodiester

Question 11

The 3’ OH of one nucleotide can form a bond with the 5’ phosphate group of another nucleotide. What does this mean for the polynucleotide chain?

Answer 11

This means that the polynucleotide chain has biological polarity or directionality, meaning that the strands always grow from 5’ to 3’.

Question 12

What are the bonds between the 3’ OH and the 5’ phosphate group?

Answer 12

Phosphodiester bonds and are very strong.

Question 13

What are the bonds between nitrogenous bases?

Answer 13

Hydrogen bonds and are much weaker than phosphodiester bonds.

Question 14

Why is it important that the hydrogen bonds are weaker between the nitrogen bases than the phosphodiester bonds?

Answer 14

The hydrogen bonds have to be weaker in order for easy separation for replication.

Question 15

Nucleic acids are ______ sugars.

Answer 15

Pentose

Question 16

What is the pentose sugar in RNA?
What about DNA?

Answer 16

Ribose is the pentose sugar in RNA.
Deoxyribose is the pentose sugar in DNA.

Question 17

What is the structural difference between Deoxyribose and Ribose?

Answer 17

There is a 2’ Hydroxyl group in Ribose, but a 2’ Hydrogen in Deoxyribose.

Question 18

What are the two classes of nitrogenous bases?

Answer 18

Pyrimidines: Contains one carbon-nitrogen ring and two nitrogen atoms
-Cytosine
-Thymine
-Uracil
Purines: A pyrimidine ring fused to an imidazole ring. Contains two carbon-nitrogen rings and four nitrogen atoms.
-Adenine
-Guanine

Question 19

Where is the nitrogenous base bound to the deoxyribose sugar?
Where is the phosphate group attached to of the deoxyribose?

Answer 19

A nitrogenous base is bound to the 1’ C of the deoxyribose sugar.
The phosphate group is attached at the 5’ position of the deoxyribose sugar.

Question 20

When is DNA double helix formed?

Answer 20

When nitrogenous bases on one DNA strand form hydrogen bonds with a complementary base on a second strand of DNA.

Question 21

When is a single strand of DNA made?

Answer 21

When nucleotides joined together by phosphodiester bond between he 5’ phosphate of one nucleotide and the 3’ OH of a neighboring nucleotide.

Question 22

What is the nature of the two strands of DNA that form the double helix? Why is it this way?

Answer 22

Antiparallel.
The antiparallel nature allows for the hydrogen bond between the nitrogenous bases, it makes the nitrogenous bases closer.

Question 23

The sugars in the backbone have directionality. What does this mean?
How do the sugars in the backbone elongate?

Answer 23

The 5’ phosphate is first and the 3’ hydroxyl is last.
The sugars elongate by the addition of dNTPs to the 3’ OH.

Question 24

Without the antiparallel nature of DNA, would replication be possible?

Answer 24

NO!

Question 25

How is RNA different than DNA?

Answer 25

Ribose sugar instead of deoxyribose, uracil instead of thymine, the complementary strand is not present (this doesn’t mean it is not doubled stranded or structured, instead it forms complementary strand bonds with itself), and it is much more sensitive to degradation and enzymes than DNA is.
Structurally, OH on the 2’ C (whereas DNA has a H on 2’C)

Question 26

What is Chargaff’s Rule?

Answer 26

A purine (A, G) can only pair with a pyrimidine (C,T).

Question 27

If you think of DNA as a spiral staircase, the nitrogenous base pairs would be?

Answer 27

“Steps”

Question 28

All “steps” (hydrogen bond) must be the same size. What happens if they aren’t?
How many angstroms (A) are there between two complementary strands of DNA? This only allows space for what?

Answer 28

The spiral will be distorted.
20 A.
This only allows space for a purine to pair with a pyrimidine.

Question 29

How are the hydrogen bonds broken between the purines and pyrimidines?

Answer 29

Easily broken with DNA helicases during replication and can be easily reformed after synthesis of new strands.

Question 30

How many hydrogen bonds are formed between A & T?
How about G & C?
Which one takes more energy to break? Do you want to start the template somewhere where it is harder or easier to break apart?

Answer 30

A & T: Two
G & C: Three
G & C bonds are harder to break (b/c there are more hydrogen bonds than A & T).
You want to start the template somewhere where it is harder to break apart.

Question 31

What are the main DNA double helix conformations?

Answer 31

B form: Watson-Crick structure, right-handed helix with 10bp per turn. The most common form.
A form: right-handed, more compact, 11 bp per turn. Shorter, wider form. Rarely found under normal physiological consequences.
Z form: left-handed, 12 bp per turn, zig-zag pattern in the phosphodiester backbone, found in GCGCGC (harder to break this run) sequences. Is a transient form of DNA. Seems that is plays an important biological role in protection against viral disease.

Question 32

The Meselson - Stahl experiment proved what?

Answer 32

That DNA is replicated semiconservatively.

Question 33

What is semiconservative replication?

Answer 33

Each strand of DNA acts as a template for the synthesis of a daughter strand.

Question 34

Describe the Meselson - Stahl Experiment.

Answer 34

E. coli cells were grown in 15N for several generations so that all the nitrogen in the DNA is heavy.
-After centrifugation in CsCl density gradient, all the DNA settles near the bottom.
Next, the ‘heavy’ E. coli are grown in 14N (light) media.
-After 1 generation, all of the DNA was ‘hybrid’ 15N-14N (heavy-light)
After another generation in 14N (light) media, both 15N-14N (heavy-light) and 14N-14N (light) DNA are present.
This proved semi-conservative replication because one strand of DNA acted as a template for each replication.

Question 35

In DNA replication, a single DNA strand can act as a _______ for the synthesis of a _______ in which each base forms a hydrogen-bonded pair with one on the template strand.

Answer 35

Template ; new nucleic acid strand

Question 36

In DNA replication, a single DNA strand can act as a template for the synthesis of a new nucleic acid strand in which each base forms a hydrogen-bonded pair with one on the template strand. The new sequence is thus _________ to the template strand.

Answer 36

Complementary.

Question 37

Define replication.

Answer 37

The copying of DNA molecules to produce more DNA is known as replication.

Question 38

Define transcription.

Answer 38

The synthesis of RNA using a DNA template is called transcription.

Question 39

Describe bacterial chromosomes.

Answer 39

Most (not all) of the bacterial chromosomes are closed circles.
Causes topological problems during DNA replication and transcription.

Question 40

Why is it a problem that bacterial double helix DNA are closed circles?

Answer 40

The DNA in front of it starts to tangle up.

Question 41

What is the nature of DNA polymerases?

Answer 41

DNApol synthesize DNA by using a single strand as a template.
DNApol can ONLY extend a DNA chain, they cannot initiate the extension.
DNApol requires a free 3’ OH to add the phosphate group of the next nucleotide to the growing chain.
Needs a primer.

Question 42

E. coli chromosomes have about _______ base pairs which results in a length of _____.

Answer 42

4.7 x 10^6
1.6 mm

Question 43

An E. coli cell is only ______ long.

Answer 43

0.002 mm

Question 44

How do bacteria solve the problem of their chromosomes being longer than their actual cells?

Answer 44

Bacteria solve this problem by compacting their DNA in the nucleoid.

Question 45

What is the bacterial nuceloid?

Answer 45

The bacterial nucleoid is an amorphous mass of DNA, unbounded by a membrane, lying in the center of the cell. It is the site of DNA and RNA synthesis.
The DNA is very tightly coiled and folded into supercoiled loops.

Question 46

What happens if one of the loops in the nucleoid breaks?

Answer 46

The whole thing comes apart, so they have histone-like proteins to help.

Question 47

Discuss the tightly coiled circular DNA in bacteria.

Answer 47

Tightly coiled circular DNA causes problems during replication and transcription. As the DNA strands are separated, the DNA in front of the replication fork becomes so supercoiled that the replication and transcription and machinery cannot continue.

Question 48

What does supercoiling refer to?

Answer 48

The twisting of the DNA double helix round its central axis, making it more compact.

Question 49

As the duplex is pulled apart at the replication fork in the closed circle, the unreplicated portion ahead of the replication fork twists so that the helix becomes…?

Answer 49

Overwound into a positive supercoil.

Question 50

Unless something happens to prevent overwinding, the positive supercoils would cause the DNA to bunch up, and further unwinding (and replication) would stop. How is this solved?

Answer 50

DNA gyrase (or topoisomerase II) relaxes the supercoiling by nicking both strands of DNA and converts them into underwound (negative supercoiled) DNA.

Question 51

Topoisomerases change what?

Answer 51

Topoisomerases change DNA topology.

Question 52

What are DNA topoisomerases?

Answer 52

Introduce (or remove) supercoils from DNA by controlled breaking and rejoining of DNA strands.

Question 53

What are type I topoisomerases?

Answer 53

Relax DNA by breaking one strand of DNA and passing the other strand through the gap, then reseals the nicked DNA.
The degree of negative supercoiling is reduced, the DNA becomes relaxed.

Question 54

What are type II topoisomerases?

Answer 54

Break both strands and pass double stranded DNA through the gap, which adds negative supercoils into the DNA.
Ex: DNA gyrase and topoisomerase IV

Question 55

Even in bacteria, with their smaller genomes, DNA replication involves…?

Answer 55

An incredibly sophisticated, highly coordinated series of molecular events. These events are divided into four major stages:
1. Initiation
2. Unwinding
3. Primer synthesis
4. Elongation

Question 56

Replication is unidirectional. T or F.

Answer 56

False, bidirectional - replicated in both directions, simultaneously.

Question 57

Where does the initiation of replication begin in prokaryotes?

Answer 57

At a precise location on the bacterial chromosome called the origin of replication.

Question 58

Most bacteria have _______ closed circular chromosomes.

Answer 58

covalently

Question 59

Most bacterial chromosomes have one origin of replication, which is?

Answer 59

oriC

Question 60

What is the origin of replication sequence (oriC) is recognized by…?

Answer 60

an initiator protein, DnaA.

Question 61

What is the function of DnaA?

Answer 61

To assemble the replication fork machinery at oriC. Within oriC, there are several DnaA boxes, DNA motifs that are DnaA recognition sites.

Question 62

Each DnaA box has a __nucleotide sequence.

Answer 62

9.

Question 63

After DnaA binds to the DnaA boxes, the _________ will be ___________.

Answer 63

AT-rich 13-mer
Unwound by a histone-like protein (HU) to form an open complex.

Question 64

After DnaA binds to the DnaA boxes, the AT-rich 13-mer will be unwound by a histone-like protein (HU). Why is it important that it is AT-rich?

Answer 64

Takes less energy to break the hydrogen bonds with AT-rich sites due to their only being two hydrogen bonds, and not three (like in GC sites).

Question 65

Before DNA synthesis can begin, what must be formed?

Answer 65

A prepriming complex.

Question 66

How is the prepriming complex made?

Answer 66

To make the prepriming complex so that two replication forks can be initiated, the two DNA strands must first unwind so that each strand can act as a template.

Question 67

The DNA-binding protein DnaA binds to the DnaA box. A histone-like protein, HU, then aids in the unwinding the AT-rich 13-mer region to form an open complex. To prevent this open complex from re-forming the duplex, what happens?

Answer 67

Single stranded binding (SBB) proteins coat the unwound strands. SBB also prevents degradation from enzymes.

Question 68

Once the open complex is formed, what happens?

Answer 68

The double stranded DNA at each replication fork must be unwound by a protein called a DnaB.

Question 69

DnaB is a…?

Answer 69

Helicase that separates complementary DNA strands.

Question 70

The helicase DnaB requires what in order to bind to DNA?

Answer 70

The helicase DnaB cannot bind to the DNA by itself, it depends on another protein, DnaC, to be transferred to the open complex.

Question 71

How do bacteria prevent the single strands of DNA (ssDNA) from coming together and forming double-stranded DNA (dsDNA)?

Answer 71

The single-stranded DNA binding protein (SSB) binds to ssDNA.

Question 72

Once the prepriming complex has been formed, what needs to happen in order for replication to happen?

Answer 72

The two strands need to be separated. This is achieved by the helicase DnaB which binds to the template strand and moves long it, separating the two strands. The separated strands are prevented from re-associating by the single-stranded DNA -binding protein SBB.

Question 73

As DnaB separates the two strands of DNA, what happens?

Answer 73

Positive supercoils form in front of the replication fork.

Question 74

As DnaB separates the two strands of DNA, positive supercoils form in front of the replication fork. What removes the positive supercoils ahead of the replication fork?

Answer 74

Type II topoisomerase, DNA gyrase.

Question 75

Describe DNA replication.

Answer 75

During replication, one of the new strands (the leading strand) can be synthesized in the 5’ to 3’ direction. The enzyme responsible for synthesis of the leading strand is DNA polymerase III.
Since nucleic acids can only be synthesized in the 5’ to 3’ direction, the 3’ to 5’ strand (the lagging strand) must be made backwards. This is done by making new strands in short fragments (Okazaki fragments). DNA polymerase III adds nucleotides in short fragments. DNA ligase fills in the gaps between Okazaki fragments, joining all the pieces together into a complete strand.

Question 76

What kind of polymerases are required for replication?

Answer 76

Both DNA polymerases and RNA polymerases.

Question 77

Discuss the roles of DNA polymerases and RNA polymerases required for DNA replication.

Answer 77

DNA polymerases can only extend a previously existing molecule - a DNA template.
DNA polymerase must have a 3’-OH to add a dNTP to.
RNA polymerases are able to initiate synthesis of new nucleic acids without a primer. Each fragment on leading and lagging strand is started with a short piece of RNA, produced by the action of special RNA polymerase (Primase). Primase synthesizes short RNA primer from DNA template.
This RNA primer can then be extended by DNA polymerase II.
The primer is subsequently removed and the gap filled in by DNA polymerase I. After the gap has been filled, the fragments that have been produced are joined together by DNA ligase.

Question 78

DNA is replicated _________.

Answer 78

Bidirectionally, minimizing replication time.

Question 79

DNA polymerase III catalyzes polymerization at ~ _________ nt/s in vivo.

Answer 79

1000

Question 80

Multiple rounds of DNA replication can occur at _____________ in actively growing cells.

Answer 80

The same time.