DNA Replication Flashcards

Question 1

Q

Central Dogma?

Answer

A

flow of genetic info goes from DNA to RNA to Protein

DNA to DNA (DNA synthesis)
DNA to RNA (Transcription)
RNA to Protein (Translation)

Transcribe= different form of the same language

Translate= different language

Question 2

Q

What are some exceptions to the central dogma?

Answer

A

Reverse transcription (retroviruses)
Non coding RNA
RNA editing
RNA replication to RNA (virus)

Question 3

Q

What makes up the structure of DNA?

Answer

A

Sugar
Nitrogenous base
Phosphate group

Question 4

Q

What is the structure of the sugar in DNA?

Answer

A

5 carbon pentose ring called ribose (RNA) or deoxyribose (DNA)

Question 5

Q

What carbon is the nitrogenous base attached to in the 5 carbon sugar of DNA?

Answer

A

1’ carbon via an N-glycosidic bond, same carbon as sugar-sugar bonds

Question 6

Q

What is difference at the 2’ carbon between DNA and RNA? Why is this significant?

Answer

A

DNA has H and RNA has OH

The absence of O makes DNA more stable, less reactive than RNA, so it is a better place to store genetic info

Question 7

Q

What does the 3’ carbon have attached in DNA/RNA?

Question 8

Q

What does the 5’ carbon have attached in DNA/RNA?

Answer

A

1 to 3 phosphate groups

Question 9

Q

What are the two types of nitrogenous bases?

Answer

A

purines (two rings)- Adenine, Guanine

pyrimidines (one ring)- Cytosine, Uracil (RNA), Thymine

Question 10

Q

What is the difference between thymine and uracil?

Answer

A

thymine contains a methyl group on the double bonded C=C2

Question 11

Q

How can cytosines next to guanines on the same strand of DNA (CpG) be modified? What does this modification do?

Answer

A

enzymatic addition of a methyl group

changes how proteins interact with DNA
influences its structure indirectly
plays a role in gene expression

Question 12

Q

Deamination?

Answer

A

spontaneous removal of an amine group (NH2) from a nucleotide, common type of DNA damage

Question 13

Q

Deamination of cytosine=?

Answer

A

Uracil, easily detected

Question 14

Q

Deamination of adenine=?

Answer

A

Hypoxanthine, easily detected

Question 15

Q

Deaminated methyl-cytosine=?

Answer

A

Thymine, not easily detected or repaired

Question 16

Q

Deaminated guanine =?

Question 17

Q

Another name for nucleotide?

Answer

A

nucleoside triphosphate

Question 18

Q

Nucleotides are the subunits of ______.

Answer

A

nucleic acids

Question 19

Q

What causes the negative charge in a nucleotide? Why is the negative charge in DNA significant?

Answer

A

phosphate (PO4^3-)

not soluble in lipids, stays in nucleus
interacts with histones for compact storage

Question 20

Q

AMP?
ADP?
ATP?

where do they attach?

Answer

A

monophospate
diphosphate
triphosphate

joined to C5 hydroxyl of ribose or deoxyribose

Question 21

Q

What type of linkage is used to attach phosphate groups to the 5’ carbon?

Answer

A

ester linkage

Question 22

Q

How are the phosphates named that are attached to the sugar? Which phosphate is included in nucleic acids?

Answer

A

alpha (closest), beta, gamma

- only alpha is included, hydrolysis of the other two provide energy for the process

Question 23

Q

What type of bond joins nucleotides together?

Answer

A

phosphodiester linkage connects the 5’ phosphate and the 3’ OH

Question 24

Q

What makes a DNA strand polar?

Answer

A

5’ PO4

3’ OH

Question 25

Q

DNA is synthesized from ___ to ____.

Question 26

Q

How are anti parallel strands of DNA primarily held together?

Answer

A

H bonds between nitrogenous bases

Question 27

Q

Which base pairs are held together tighter? (AT or GC). Why?

Answer

A

GC because they are held together by 3 H bonds whereas AT is held together by 2 H bonds

-purines always pair with pyrimidines

Question 28

Q

What is the backbone of DNA strands composed of?

Answer

A

sugar and phosphate

Question 29

Q

In an alpha helix, where do the bases lie in relation to the axis of symmetry?

Answer

A

perpendicular

Question 30

Q

What is the purpose of the alpha helix? How many bp/turn?

Answer

A

it compacts DNA

10 bp/turn

Question 31

Q

Where are the major and minor grooves located in an alpha helix? What is significant about them?

Answer

A

major- between turns

minor- between strands

-this is where proteins interact with DNA

Question 32

Q

What is significant about DNA having complimentary base pairs and antiparallel structure?

Answer

A

Allows both strands to be used as templates for DNA synthesis, which ensures that each daughter cell gets the same genetic information.

Allows DNA repair to occur, since the damaged strand can be repaired by using the complimentary sequence as a template.

Question 33

Q

What is chromatin?

Answer

A

DNA + proteins

Question 34

Q

What is the difference between Euchromatin and Heterochromatin?

Answer

A

Euchromatin- less condensed, transcriptionally active, on chromosome arms, unique sequences, many genes, throughout S phase, crossing over common

Hetero- inactive, more condensed, sometimes facultative, always constitutive, at centromeres, telomeres, repeated sequences, few genes, late S phase, crossing over uncommon

Question 35

Q

What is the size of the nucleus?

Answer

A

5-8 micrometers diameter

Question 36

Q

What happens during Mitosis to chromatin?

Answer

A

becomes very condensed, chromosomes become visible

Question 37

Q

Where is the site for Ribosome synthesis is the nucleus?

Question 38

Q

How many base pairs are packed into the Nucleus?

Answer

A

3 billion in an organized way for replication and transcription, compaction ration of 10,000 to 1

Question 39

Q

What are histones?

Answer

A

small positively charged proteins

Question 40

Q

What is the nucleosome core composed of?

Answer

A

H2A, H2B, H3, H4

-2 of each to make an octamer

Question 41

Q

How does DNA pack around histones?

Answer

A

wraps twice around octamer to make a nucleosome bead

Question 42

Q

What is linker DNA?

Answer

A

about 50 base pairs of DNA that separate the nucleosomes

Question 43

Q

What is the role of H1?

Answer

A

bind linker DNA

Question 44

Q

How much do nucleosomes decreases the length of DNA by?

Question 45

Q

What is the nucleofilament?

Answer

A

30 nm fibers of packed nucleosomes in a 2 start helix consisting of 2 strands of nucleosomes stacked like coins

Question 46

Q

What is the order of compaction from DNA to chromosome?

Answer

A

DNA
Nucleosome beads- histone plus DNA
30 nm fiber nucleofilament
nucleofilament is coiled and anchored to scaffold protein
Chromosome

Question 47

Q

How do histones hold onto DNA?

Answer

A

positively charged tails of nucleosomal histone proteins that contain lysine amino acids interact with the negatively charged phosphate groups of DNA

Question 48

Q

What post translational modification occurs to weaken histone interaction with DNA?

Answer

A

acetylation of tails weakens interaction with DNA and allows some transcription factors to bind DNA

Question 49

Q

What is the role of histone acetyl transferases (HAT)?

Answer

A

add acetyl groups to loosen interaction with DNA, this favors Euchromatin
positively acting transcription factors or proteins recruited often have HAT activity

Question 50

Q

What is the role of histone deacetylases (HDAC)?

Answer

A

remove acetyl groups to increase interaction with DNA, favors heterochromatin
transcriptional repressors often recruit proteins with HDAC activity

Question 51

Q

What are other post translational modifications of histones and their role?

Answer

A

-phosphorylation, methylation, ubiquitination

make up a complex histone code, which influences chromatin structure and gene expression
affect histone interaction with DNA, histones, proteins

Question 52

Q

What phase of the cell cycle does DNA replication occur?

Answer

A

S (synthetic) phase- discrete phase

-replicate 3 billion bp in 6-8 hours

Question 53

Q

What regulates passage between phases of the cell cycle?

Answer

A

cyclins and associated kinases (cyclin dependent kinases- CDK)

Question 54

Q

What controls checkpoints in the cell cycle?

Answer

A

tumor suppressors (p53, pRB)

-keeps cell cycle from moving forward

Question 55

Q

Role of proto oncogenes? abnormal?

Answer

A

send positive signals for continued cycling (c-myc, Ras)

- abnormal = cancer

Question 56

Q

What happens in the cell cycle if DNA damage is detected? what if it cannot be repaired?

Answer

A

cell cycle is halted
DNA repair pathways are initiated

-if damage cannot be repaired, cell undergoes apoptosis or programmed cell death

Question 57

Q

What is licensing in the cell cycle? When does it occur?

Answer

A

In late G1 and S phase, licensing ensures that all regions or origins of DNA are replicated completely, but only once per cycle
when the origin fires in S phase, the license is removed, since only licensed origins can replicate, this ensures that the same are is not replicated twice

Question 58

Q

What regions of the genome are replicated early in S phase? later in S phase?

Answer

A

actively transcribed regions are replicated early, where untranscribed regions are replicated later

Question 59

Q

What are the steps of the cell cycle?

Answer

A

G1- cell growth and metabolism
Go- non dividing phase in G1
G1/S check- cell is committed to dividing
S- DNA replication
G2- cell prepares for Mitosis
G2/M check- cell can divide
Mitosis/Cytokinesis- cell divides

Question 60

Q

What does semiconservative mean?

Answer

A

-each of the two new daughter helices contains one stand of parental DNA and one strand of new DNA

both parent strands are used as templates
both daughter cells get the same genetic info

Question 61

Q

Explain the origins of replication in Eukaryotes? Forks? Bubbles?

Answer

A

there are multiple origins of replication along a chromosome and replication is bidirectional, this allows the process to be more efficient and faster
replication forks- regions of transition between unwound parent duplex and newly replicated daughter DNA
replication bubbles- unwound region

Question 62

Q

What are origins rich in (AT or GC)? Why?

Answer

A

AT rich because they are easier to split

-euchromatin origins are first

Question 63

Q

DNA polymerase works in what direction?

Answer

A

synthesizes 5’ to 3’

Question 64

Q

Describe the process of initiation in Replication?

Answer

A

large protein complex called Origin Recognition Complex (ORC) assembles at the origin throughout the cell cycle, cannot initiate
Cdc6 and Cdt1 recruit Mcm helices in late G1 phase to form a pre-replicative complex (pre-RC). Now the origin is licensed to replicate
At the beginning of S phase, S-CDK phosphorylates Mcm and ORC which disassembles the pre-RC and initiates DNA replication
Phosphorylated Mcm forms the replication bubble and allows the pre initiation complex to form, which contains DNA polymerase and other proteins. Mcm goes with the replication forks to help separate the strands
ORC binds the origins of both daughter DNAs, and stays phosphorylated until G1 so that it cannot bind Cdc6 and form the pre-RC until the next S phase

Answer 60

A

re-replication = cancerous cells

Answer 61

A

move along one strand of DNA and change the conformation to bind the double strand, then use ATP to separate the two strands and return to their original conformation

Answer 62

A

bind to the single stranded regions of the replication bubble and prevent the two strands from reannealing to each other or base pairing with themselves (hairpins, DNA pol passes them, could cause deletion)

Answer 63

A

make reversible nicks in the DNA ahead of the replication fork, pass the unbroken strand through the gap and then reseal the gap, prevents supercoiling

Answer 64

A

make double stranded breaks in the DNA, allow uncoiling, and then re-ligate, prevents supercoiling

Answer 65

A

if Topoisomerase is not working due to the drug, the DNA will supercoil, causing double strand breaks in the DNA that cannot be repaired, leading to apoptosis

Answer 66

A

New DNA is synthesized from dNTPs
In replication, the 3’ OH group of the last nucleotide on the strand attacks the 5’ phosphate group of the incoming dNTP
Two phosphates are cleaved off by hydrolysis for energy
phosphodiester bond forms between the the two nucleotides

Answer 67

A

it moves 3’ to 5’

synthesizes 5’ to 3’

Answer 68

A

RNA primer made by Primase (RNA polymerase)

Answer 69

A

allows it to proofread by excising the last nucleotide added if it doesn’t base pair correctly with the template, very accurate

Answer 70

A

continuously from the origin, in the same direction as the replication fork

Answer 71

A

discontinuously in small fragments beginning in the replication fork and moving toward the origin, a new primer must be generated the beginning of each okasaki fragments

Answer 72

A

RNA hydrolyses or RNAses

Answer 73

A

uses ATP to make the final phosphodiester bond to seal the nicks and join the fragments together

Answer 74

A

Origin + ORC + Cdc6 + Cdt1 + Mcm = pre-RC, license is created, phosphorylated in S phase
Helicases unwind the strand, bubble forms
Single stranded binding protein (RPA) keeps parental strand from reannealing
Topoisomerase prevents supercoiling
Primase makes RNA primers
DNA pol synthesizes 5’ to 3’
RNAse removes primers, gaps filled by DNA pol
DNA ligase seals the nicks

-at least 30 different proteins are involved

Answer 75

A

sliding clamp that increases processivity of DNA polymerase (helps it stay on DNA)

-it is also involved in DNA repair, chromatin remodeling, cell cycle regulation

Answer 76

A

alpha
delta
epsilon

Answer 77

A

the study of heritable changes in gene expression that occur without changes in DNA primary sequence

Answer 78

A

Genetic- DNA sequence change is passed to the next generation

Epigenetic- chromatin change is multiplied in somatic cells (mitotically heritable) within the same organism, but is not passed on to the next generation

Answer 79

A

-histone modifications and DNA methylation, these patterns are maintained during DNA replication

Answer 80

A

by regulating the accessibility of the DNA to transcription factors through effects on chromatin structure, affect tightness

most are erased during production of germ cells
can be influenced by intra and extracellular environment

Answer 81

A

on cytosines next to guanines on the same strand of DNA (CpG sequences), 5-methylcytosine is created

Answer 82

A

associated with mitotically heritable gene inactivation, inhibits transcription
important for normal development, X chromosome inactivation, imprinting-one allele shut off
maintains chromosomal stability by keeping repetitive sequences in non coding regions in a repressed state

Answer 83

A

TpG due to CpG being methylated and deaminated

-remaining CpG are not evenly distributed in the genome

Answer 84

A

C-G rich areas, often at the 5’ end of genes (housekeeping genes that constitutively expressed), normally not methylated

Answer 85

A

most CpG sequences were methylated in the germ line except for areas with closed chromatin
the closed chromatin were maintained because they weren’t methylated

Answer 86

A

DNA maintenance methylase (DMNT1) recognizes hemi-methylated sites and it methylates the newly synthesized strand

Answer 87

A

acetylation
methylation
phosphorylation
ubiquitination

modifications- epigenetic signal that helps regulate gene expression

Answer 88

A

During replication, histones are distributed between daughter DNA, leaving gaps
newly synthesized histone proteins bind the gaps and are modified by Reader Writer Remodeling Complexes (RWRC) to match the ones already bound

-other chromatin proteins also get distributed the same way to maintain structure

Answer 89

A

the removal of the RNA primer from the end of the lagging strand leads to loss of some DNA

Answer 90

A

Telomeres

Answer 91

A

protect ends of chromosomes from degradation and fusion

2. distinguish ends of intact chromosomes from broken ones

Answer 92

A

Loss of telomeric DNA, fewer proteins can bind, risk that telomeres will not be able to protect end of chromosomes, triggers cell cycle checkpoint mechanism and cell stops growing permanently
may be related to aging

Answer 93

A

germline cells, stem cells, over 85% cancer cells

- not found in somatic cells

Answer 94

A

reverse transcriptase
uses its own RNA template complimentary to G rich strand of telomere, to extend 3’ end of parental strand, length of telomeres is maintained
key player in immortalization- can keep replicating

Answer 95

A

these checkpoints fail which causes the cells to keep replicating their DNA even though the telomeres are dangerously short

Answer 96

A

chromosomal instability, very few cells have telomerase that can be activated

Answer 97

A

evolved from symbiotic bacteria in early eukaryotes
contain 13 proteins that are transcribed and translated to function in mitochondria
most other proteins are made in the nuclear genome, translated in cytosol, and are imported to mitochondria

Answer 98

A

single, double helical circle, no histones

- multiple copies of DNA per mitochondrion and multiple mitochondria per cell

Answer 99

A

False

every cell varies, number of mitochondria changes with changes in physiological conditions, some cells need more energy output such as muscle cells

Answer 100

A

No, it is not limited to S phase, it resembles bacterial replication
No, code is slightly different

Answer 101

A

mitochondria because nearly every base pair is used to make a functional product, nuclear genome has many repetitive sequences

Answer 102

A

Mitochondrial (5-10X higher) due to its close proximity to sites of generation of oxygen radicals, or could be due to less efficient repair mechanisms
contributes to decreased efficiency of oxidative metabolism with increased age, and aging in general

Answer 103

A

it correlates better to the complexity of an organism rather than number of genes

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DNA Replication Flashcards

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