DNA Hybridisation, Complementarity and Its Application

Question 1

What is RNA and DNA made up of?

Answer 1

Nucleotides

Question 2

What is DNA?

Answer 2

DNA is a polymer / polynucleotide comprising of 4 nucleotides

Question 3

Describe the structure of a nucleotide

Answer 3

Nitrogenous Base:
Phosphate group
Pentose Sugar

Question 4

What is the structure of the nitrogenous base?

Answer 4

a ring structure composed of carbon and nitrogen

Question 5

What is a pentose sugar?

Answer 5

5 carbons (numbered 1 - 5) that form a cyclical structure with oxygen bridge
Hydroxyl OH group carbon 3

Question 6

Where does the nitrogenous base join the pentose sugar in a nucleotide?

Answer 6

Nitrogenous base joined to carbon 1

Question 7

Where does the phosphate group lie in relation to the pentose sugar in a nucleotide molecule?

Answer 7

Phosphate group joined to carbon 5 - forms phosphodiester bond with OH on adjacent carbon on next base

Question 8

What is the difference between RNA and DNA structure?

Answer 8

RNA also has 2nd OH group at carbon 2

Question 9

What are purine bases?

Answer 9

double ringed e.g.

guanine, adenine (G,A)

Question 10

What are pyrimidine bases?

Answer 10

single ringed bases e.g.

thymine, cytosine (T,C)

Question 11

How do bases form specific pairs?

Answer 11

Charged polar groups provide the specificity of base pairing

Question 12

How does base pairing differ between RNA and DNA?

Answer 12

In RNA Uracil substitutes Thymine and base pairs with Adenine in RNA to form duplex structure

Question 13

How does base pairing form a double helix?

Answer 13

Hydrogen bonding between oppositely charged groups forms basis of Watson and Crick base pairing forming the double helix

Question 14

Where on the bases does the Hydrogen bond form?

Answer 14

Hydrogen bonding involves amine and carboxyl groups between Adenine and Thymine or between Guanine and Cytosine

In each pair there is a single purine and pyrimidine

Question 15

Why is Cytosine-guanine pairing stronger than adenine- thymine/uracil pairing?

Answer 15

There is an extra Hydrogen bond between C-G than A-T/U

Question 16

How do nucleotides join to one another to form the sugar-phosphate backbone?

Answer 16

linked by phosphodiester bonds C3

O bonds to phosphate group

Question 17

How does base stacking occur in a double helix?

Answer 17

hydrophobic interactions -> arrangement of bases set above each other internalised to the structure & excludes water

Question 18

What is the significance of Van der Waals forces in DNA?

Answer 18

individually small but contributes to the stability

Question 19

What conformations does the DNA double helix form?

Answer 19

A, B and Z forms

B form is most common

Question 20

What forms the DNA backbone?

Answer 20

The DNA backbone is formed from phosphodiester linkages connecting 3 and 5 prime carbons of the DNA deoxyribose sugar

Question 21

What determines DNA stability?

Answer 21

The structure stability is determined by the free energy of the molecule and energy minimisation just as in protein structure

Question 22

What directions do the two DNA strands forming the double helix run along?

Answer 22

Double stranded helix is formed from 2 antiparallel strands

5’-3’and 3’-5’

Question 23

Why does DNA have a negative charge?

Answer 23

The bases are on the inside forming stacked bases and the negatively charged phosphates are external giving DNA an overall negative charge

Question 24

What is meant by denaturing DNA?

Answer 24

Conversion of a double stranded molecule → single stranded molecules

Question 25

What is denaturing of DNA?

Answer 25

Denaturing is the disruption of Hydrogen bonds within the double helix

Question 26

When does DNA denaturing occur?

Answer 26

• DNA in solution heated to energise bonds
• Or induced by strong alkali / urea, forms randomly
  structured coil

Question 27

How is denaturing measured?

Answer 27

Denaturation can be measured optically by absorbance at 260nm

Question 28

What is hyperchromicity?

Answer 28

Increase of absorbance (optical density) of a material

Increased absorption of light at 260nm On denaturation

Question 29

Which type of DNA (ss/dsDNA) absorbs more UV light?

Answer 29

Single stranded DNA absorbs more UV light than double stranded DNA (hyperchromicity)

Question 30

What determines how well DNA denatures?

Answer 30

The denaturing of a specific DNA depends upon the stability of the specific structure

Question 31

What is the Tm?

Answer 31

Point at which 50% of all strands separate is called the melting temperature or Tm

Question 32

What is the significance of Tm?

Answer 32

The Tm is specific to individual double helices and is used to control its formation

Question 33

What factors determine the Tm of a DNA molecule?

Answer 33

Tm depends largely on hydrogen bonds affected by:

• GC content
• Length of DNA molecule
• Salt concentration (environment)
• pH (alkali is a denaturant)
• Mismatches (unmatched base pairs)

Question 34

How does the GC content affect Tm?

Answer 34

Higher GC content = more H bonds = higher Tm

3 H+ bonds in G:C vs 2 in A:T
∴ more G:C pairing = more H+ bonds

Question 35

How would you calculate the % of GC base pairs in a DNA strand?

Answer 35

%GC = (G+C / G+C+A+T) x 100

Question 36

How does molecule length affect the Tm?

Answer 36

Longer the contiguous duplex, the higher Tm
More Hydrogen bonds within the molecule greater stability

However little further contribution beyond 300 bp

Question 37

How does the salt concentration affect Tm?

Answer 37

Salt stabilises DNA duplexes

High [Na+] = High Tm

Question 38

How does increasing [salt] overcome base pairing mismatches?

Answer 38

Increasing salt concentration stabilises the structure, increases the Tm and thus overcomes the destabilising effect of mismatched base pairing

Question 39

What is the effect of a high [salt] of DNA?

Answer 39

High salt reduces the specificity of base pairing at a given temperature

Question 40

How does [salt] affect duplex stability?

Answer 40

A duplex containing mismatches can form and be stable at a given temperature in the presence of high [salt]
whilst the same duplex would be unstable and dissociate at the same temperature in low salt

Question 41

How does pH affect the Tm?

Answer 41

Chemical denaturants disrupt hydrogen bonds e.g. Alkali, formamide, urea

NaOH ⇆ Na+ + OH-
OH- disrupts H bond pairing

Fewer hydrogen bonds = Lower Tm

Question 42

What is the effect of high pH on stability of DNA duplexes?

Answer 42

High pH (alkalinity) destabilises DNA duplexes

Question 43

What is a mismatch?

Answer 43

A mismatch is defined as a base pair combination that is unable to form hydrogen bonds

Question 44

What effect does mismatches have on the Tm of DNA?

Answer 44

Reduces Number of Hydrogen bonds, Fewer = lower Tm

Question 45

What effect does mismatching have on the structure of a DNA duplex?

Answer 45

Mismatches also distorts the structure and destabilises adjacent base pairing

Question 46

What is renaturation?

Answer 46

The reversal of denaturation

Question 47

Explain renaturation in terms of free energy

Answer 47

Formation of structure favours energy minimisation driven by change in free energy DG

Question 48

What is renaturation facilitated by?

Answer 48

Slow Cooling

Neutralisation

Question 49

Explain how renaturation and hybridisation differ?

Answer 49

Renaturation :
forming a duplex from single strands that were once already a double helix

Hybridisation :
formation of a duplex structure of 2 DNA molecules that have been introduced to one another
e.g., a short synthetic DNA (or primer) and genomic DNA

Question 50

What determines the specificity of base pairing?

Answer 50

Complementarity and Tm is the basis of specificity

Question 51

Outline what a perfect match would involve

Answer 51

• Have a higher Tm
• Thermodynamically favoured over Mismatches
• Property can be used to form a complementary molecule
  with no mismatches

Question 52

How can we prevent mismatches forming between two molecules?

Answer 52

Since mis-matches destabilise DNA and reduce the Tm preventing mismatches forming between two molecules can be achieved by performing a hybridisation at the Tm of the duplex molecule

Question 53

What is stringency?

Answer 53

Stringency is the concept of manipulating the conditions to select duplexes with a perfect match only

Question 54

What does manipulating conditions of hybridisation allow us to do?

Answer 54

Limiting hybridisation between imperfectly matched sequences allows us to manipulate (increase) specificity

Question 55

Explain the outcome of hybridisation under high stringency

Answer 55

Only complementary sequences are stable (no mismatches) determined by a

• Temperature near Tm
• Low salt concentration

Question 56

What is the effect of hybridisation under low stringency?

Answer 56

multiple duplexes form containing different mismatch pairings

Question 57

Which methods use Complementarity and hybridisation techniques?

Answer 57

Northern blotting
Southern blotting
Microarrays
Dideoxy and Next Gen Sequencing
PCR
Cloning

All rely on complementary base pairing specificity and avoidance of mismatches using Tm + manipulating conditions of hybridisation

Question 58

What is the significance of Nucleic Acid Hybridisation Techniques?

Answer 58

Identifies presence of nucleic acids containing a specific sequence of bases
Allows the absolute / relative quantitation of these sequences in a mixture

Question 59

Why are nucleic acids so important for hybridisation?

Answer 59

Hybridisation uses the ability of NA to form specific duplexes

Question 60

What is a probe?

Answer 60

A ssDNA (or RNA) molecule
Typically 20 – 1000 bases in length

Question 61

How are probes identifiable?

Answer 61

Labelled with a fluorescent or luminescent molecule (less commonly a radioactive isotope)
In some techniques thousands or millions of probes are used simultaneously

Question 62

Explain how probes are used to identify specific base sequences

Answer 62

Probes used to detect nucleic acids are designed to be complementary to a specific target gene sequence region which is unique to that gene, which under high stringency conditions form a duplex

Question 63

How are probes able to identify specific sequences?

Answer 63

Uses the complementarity and hybridisation of labelled nucleic acids

Question 64

What is Northern Blotting?

Answer 64

Northern Blotting is a technique adapted from Southern Blotting for analysing the genes that are expressed by a cell tissue or organ

Question 65

Outline the technique of Northern Blotting

Answer 65

1. Southern / Northern blotting uses DNA / RNA which is
   separated by gel electrophoresis
2. Transferred by mass capillary flow to a nylon membrane
3. Covalently bond to membrane and then hybridised with
   a labelled probe
4. The probe can be visualised by some means

Question 66

What is the use of Northern Blotting?

Answer 66

Analysis of mRNA or DNA

Question 67

What are the drawbacks of northern blotting technique?

Answer 67

Limited technique: only detects one gene at a time and small numbers of samples

Gel based techniques are time consuming and messy

Largely Superseded by quantitative PCR

Question 68

What is a microarray?

Answer 68

An ordered assembly of thousands nucleic acid probes

can also assess millions of SNPs

Question 69

Explain how microarrays work

Answer 69

Probes are fixed to a solid surface, then sample of interest is hybridised to the probes
Simultaneously measuring 50,000 different transcripts in a Cell, Tissue or Organ

Question 70

What are microarrays used for?

Answer 70

microarray might be used for gene expression profiling for example a comparison of drug treated cells and untreated cells (compares gene expression)

Question 71

Outline the process of microarrays

Answer 71

1. RNA is extracted
2. Labelled
3. Hybridised to array and amount + location of label is
   measured
4. This tells us how much of each and everyone of the
   transcripts in the human genome are being expressed

Question 72

How many SNPs can be detected from 1 persons DNA?

Answer 72

DNA from 1 person on 1 microarray
Detects 2.5 million SNPs simultaneously
Result: homozygous or heterozygous for each SNP
e.g. rs1333049: CC, GG or CG
Used in Genome Wide Association studies (GWAS)

Question 73

What is an SNP?

Answer 73

Single-nucleotide polymorphism
most common type of genetic variation among people
Each SNP represents a difference in a single nucleotide