Next Generation Sequencing

Question 1

When was the human genome project completed?

Answer 1

Human Genome Project (1990 - 2003) costing $3bn

Question 2

How base pairs long is the human genome project?

Answer 2

3 billion base pairs long

Question 3

What technique was used to produce the human genome?

Answer 3

All done with traditional Sanger Sequencing

Question 4

What is the significance of the human genome project?

Answer 4

Unravelled the first Human Genome Sequence to drive genetics research
We can now achieve this amount of sequencing in as little time as one day!

Question 5

What is the use of PCR?

Answer 5

PCR is used to amplify a specific region of DNA; primers flank the region you want to amplify
- Amplify enough DNA molecules so that we have sufficient material to sequence or for other applications

Question 6

Why is PCR so significant?

Answer 6

Fundamental for any DNA sequencing application

Question 7

Why is PCR so great at amplifying DNA?

Answer 7

Each cycle doubles the amount of DNA copies of your target sequence

Question 8

What is Sanger Sequencing?

Answer 8

Invented by Fred Sanger back in 1977
Cycle Sequencing; based on the same principles as PCR
Each of the 4 DNA nucleotides has a different dye so we can determine the nucleotide sequence

Question 9

Outline the advantages of Sanger Sequencing

Answer 9

• Up to 800 bp of sequence per reaction
• Accurate (99.99%)
• One reaction = one sequence

Question 10

Outline the disadvantages of Sanger sequencing

Answer 10

• Slow and low-throughput

- Costly to perform ££££

Question 11

What are the benefits of next generation sequencing?

Answer 11

Technological advances since the end of the human genome project
Decrease in the cost of DNA sequencing: since2007, the cost has dropped at a rate faster than that of Moore’s law

Question 12

Describe the 4 key principles of NGS

Answer 12

DNA library Construction
Cluster Generation
Sequencing-by-synthesis
Data analysis

Question 13

What is a DNA library?

Answer 13

A DNA library is a collection of random DNA fragments of a specific sample to be used for further study; in our case next generation sequencing

Question 14

Where do we obtain DNA from for DNA libraries?

Answer 14

The DNA can come from just about anywhere, but in human genetic research generally it’s derived from patients blood.

Question 15

How is DNA prepared for a DNA library construction?

Answer 15

In the wet lab DNA prepped for sequencing
DNA chopped into small 300 bp fragments
=> Shearing

Question 16

How is shearing achieved?

Answer 16

Shearing achieved chemically, enzymatically or physically (sonication)

Question 17

How are the ends of the sheared DNA repaired?

Answer 17

Adenine (A) nucleotide overhangs are added to the end of fragments
Adapters with Thymine (T) overhangs can be ligated to the DNA fragments

Question 18

Describe the products of DNA library construction in NGS

Answer 18

The end result is the DNA library of literally billions of small, stable random fragments representative of our original DNA sample

Question 19

What are adaptors used for in NGS DNA library constructions?

Answer 19

Adapters contain the essential components to allow the library fragments to be sequenced

Question 20

What is the purpose of P5 and P7 anchors?

Answer 20

P5 and P7 anchors for attachment of library fragments to the flow cell

Question 21

How does cluster generation occur?

Answer 21

Hybridise DNA library fragments to the flowcell (microscope slides sandwiched together)
This is a random process

Question 22

Why do we carry out PCR during cluster generation?

Answer 22

We can’t see individual single molecules of DNA library –too small
We use PCR to amplify the fragments to a visible size

Question 23

How are clusters generated during NGS?

Answer 23

Bridge PCR generates clusters originating from the single DNA library molecules
Clusters are now big enough to be visualised

Question 24

How is sequencing of the clusters by sequencing carried out?

Answer 24

Sequence each nucleotide 1 cycle at a time in a controlled manner
Modified 4 bases (ATCG) with chain terminators AND a different fluorescent colour dye

Question 25

Explain how sequencing by synthesis occurs?

Answer 25

1. Single nucleotide incorporation (DNA polymerase)
2. Flowcell wash
3. Image the 4 bases (digital photograph)
4. Cleave terminator chemical group and dye with enzyme

• repeat n times for a full length sequence

Question 26

How is the sequencing by synthesis presented?

Answer 26

Camera sequentially images all 4 bases on the surface of the flowcell each cycle

Question 27

What can we determine from each cycle image of the flowcell?

Answer 27

Each cycle image is converted to a nucleotide base call (ACGT)

Question 28

How many cycles are there for each flow cell?

Answer 28

Cycle number anywhere between 50 – 250 nucleotide base pairs

Question 29

How do we analyse short read sequences produced via NGS?

Answer 29

To generate a consensus sequence of our original DNA samples short read sequences from the machine need to be re-assembled like a jigsaw

Question 30

How can we use the consensus sequence to identify genetic variants?

Answer 30

We can compare this consensus sequence against the human genome reference and look for the genetic variants

Question 31

What tools are used to compare consensus sequences to the human genome?

Answer 31

Dedicated software and bioinformatics tools will achieve this

Question 32

Approximately how many genes are there in the human genome?

Answer 32

There are ~21,000 genes in the human genome

Question 33

Of the human genome, which areas are most interesting to study for variants?

Answer 33

Often we are only interested in the gene protein coding exons or ‘exome’ represents 1-2% of the genome

Question 34

How many pathogenic mutations are found in exomes?

Answer 34

Some ~80% pathogenic mutations are protein coding

Question 35

What is the benefit of only looking at the exome?

Answer 35

More efficient to only sequence the bits we are interested in, rather than the entire genome
Costs £1,000 for a genome, but only £200-£300 for an exome

Question 36

How is exome sequencing achieved using target enrichment?

Answer 36

1. Samples + buffer + baits
2. Hybridisation occurs
3. Add coated magnetic beads
4. Capture beads bound to samples
5. Unbound traction discarded
6. Wash beads and digest RNA
7. Amplify for sequencing

Question 37

Why is target enrichment a good method used to prep samples for amplification?

Answer 37

Potential to capture several Mb genomic regions of interest

Exome would be 50Mb

Question 38

How does NGS differ from Sanger sequencing?

Answer 38

NGS

• produces a digital readout.
• consensus sequence of many reads

Sanger

• produces an analogue readout
• one sequence read

Question 39

How can genetic diseases be explored using NGS?

Answer 39

Collecting disease affected individuals and their families
Perform exome sequencing
Incorporation of NGS into disease gene identification

Question 40

Where is RNA obtained for RNA sequencing using NGS?

Answer 40

RNA-seq experiments use the total RNA (or mRNA) from a collection of cells or tissue

Question 41

Outline how NGS is used for RNA sequencing

Answer 41

1. RNA is first converted to cDNA prior to library
   construction
2. NGS of RNA samples determine which genes are
   `actively expressed

Question 42

How can we determine gene abundance from NGS RNA sequencing?

Answer 42

The number of sequencing reads produced from each gene can be used as a measure of gene abundance

Question 43

How is NGS RNA Sequencing able to help us identify differing gene expressions

Answer 43

With appropriate analysis, RNA-seq can be used to discover distinct isoforms of genes are differentially regulated and expressed

Question 44

What methods are used in third-generation sequencing?

Answer 44

Oxford Nanopore sequencing
Single-molecule sequencing
No PCR involved

Question 45

How is third-generation sequencing carried out?

Answer 45

DNA passes through a nanopore and base sequence is converted into an electrical current