1. DNA Sequencing

2. DNA sequencing How we obtain the sequence of nucleotides of a species
…ACGTGACTGAGGACCGTG
CGACTGAGACTGACTGGGT
CTAGCTAGACTACGTTTTA
TATATATATACGTCGTCGT
ACTGATGACTAGATTACAG
ACTGATTTAGATACCTGAC
TGATTTTAAAAAAATATT…

3. Which representative of the species?
Which human?
Answer one:
Answer two: it doesn’t matter
Polymorphism rate: number of letter changes between two different members of a species
Humans: ~1/1,000
Other organisms have much higher polymorphism rates
Population size!
Just beneath the surface of the ocean floats a tiny egg. Within it's hull of follicle cells the embryo of Ciona, a sea squirt or Ascidian, is beginning to develop. The shape of the egg does not give any clue of the creature that it is going to be. Now about a third of a millimeter it is waiting to become a larva, and this larva is a rather surprising creature.
The larva is developing within a few weeks. A head and a tail are evolving. When you look carefully you can see a rod that stiffens the tail. We know such a device as a notochord. A trained zoologist would identify the animal as belonging to the Phylum Chordata, and that is the same group we humans belong to. (See footnote).
Also the internal organs are beginning to show. But the image is a bit deceiving. What seems to be an eye is in fact a device for equilibrium called the 'Otolith'. Above it we find the light sense organ, the 'Ocellus'
So there is something suspicious about these so-called sea squirts. Freed from it's shell a familiar form has appeared. Clearly the resemblance with a tadpole larva is seen. The little creature swims for a few hours to find a good spot somewhere on a solid surface. Then a surprising thing happens.
This larva is not going to evolve into a fish, amphibian or anything like that. With the front of it's head it attaches itself to a surface. Within minutes resorption of the larva tail commences and the sea squirt will stay on that same spot for all it's life

5. Human population migrations
Out of Africa, Replacement
Single mother of all humans (Eve) ~150,000yr
Single father of all humans (Adam) ~70,000yr
Humans out of Africa ~40000 years ago replaced others (e.g., Neandertals)
Evidence: mtDNA
Multiregional Evolution
Fossil records show a continuous change of morphological features
Proponents of the theory doubt mtDNA and other genetic evidence

6. Why humans are so similar
A small population that interbred reduced the genetic variation
Out of Africa ~ 40,000 years ago
Out of Africa
H = 4Nu/(1 + 4Nu)

7. Migration of human variation

8. Migration of human variation

9. Migration of human variation

10. Human variation in Y chromosome

13. DNA Sequencing – Overview
1975
Gel electrophoresis
Predominant, old technology by F. Sanger
Whole genome strategies
Physical mapping
Walking
Shotgun sequencing
Computational fragment assembly
The future—new sequencing technologies
Pyrosequencing, single molecule methods, …
Assembly techniques
Future variants of sequencing
Resequencing of humans
Microbial and environmental sequencing
Cancer genome sequencing
2015

14. DNA Sequencing Goal: Find the complete sequence of A, C, G, T’s in DNA
Challenge:
There is no machine that takes long DNA as an input, and gives the complete sequence as output
Can only sequence ~500 letters at a time

15. DNA Sequencing – vectors
Shake
DNA fragments
Known
location
(restriction
site)
Vector
Circular genome
(bacterium, plasmid) + =

16. Different types of vectors
Size of insert
Plasmid
2,000-10,000
Can control the size
Cosmid
40,000
BAC (Bacterial Artificial Chromosome)
70, ,000
YAC (Yeast Artificial Chromosome)
> 300,000
Not used much recently

17. DNA Sequencing – gel electrophoresis
Start at primer (restriction site)
Grow DNA chain
Include dideoxynucleoside (modified a, c, g, t)
Stops reaction at all possible points
Separate products with length, using gel electrophoresis

18. Electrophoresis diagrams

19. Challenging to read answer

20. Challenging to read answer

21. Challenging to read answer

22. Reading an electropherogram
Filtering
Smoothening
Correction for length compressions
A method for calling the letters – PHRED
PHRED – PHil’s Read EDitor (by Phil Green)
Several better methods exist, but labs are reluctant to change

23. Output of PHRED: a read A read: 500-1000 nucleotides
A C G A A T C A G …A
…21
Quality scores: -10log10Prob(Error)
Reads can be obtained from leftmost, rightmost ends of the insert
Double-barreled sequencing: (1990)
Both leftmost & rightmost ends are sequenced, reads are paired

24. Pyrosequencing / 454
Image credits: 454 Life Sciences

25. Solexa / ABI SOLiD
Image credits: Illumina, Applied Biosystems

26. Illumina / Affymetrix genotyping
Image credits: Illumina, Affymetrix

27. Other technologies in development

28. Mammalian resequencing
Comparison
Technology
Read length (bp)
Pairing
bp / $
de novo
Sanger
1,000
long-range
yes
454
250
short-range
10,000
Solexa/ABI 30
100,000
maybe
SNP chips 1 no
5,000
Application
Sanger
454
Solexa/ABI
SNP chips
Bacterial sequencing  
probably
Mammalian sequencing ?
probably not
Mammalian resequencing
expensive
Genotyping

29. Method to sequence longer regions
genomic segment
cut many times at random (Shotgun)
Get one or two reads from each segment
~500 bp
~500 bp

30. Reconstructing the Sequence (Fragment Assembly)
reads
Cover region with ~7-fold redundancy (7X)
Overlap reads and extend to reconstruct the original genomic region

31. Definition of Coverage
Length of genomic segment: L
Number of reads: n
Length of each read: l
Definition: Coverage C = n l / L
How much coverage is enough?
Lander-Waterman model:
Assuming uniform distribution of reads, C=10 results in 1 gapped region /1,000,000 nucleotides

32. Repeats Bacterial genomes: 5% Mammals: 50% Repeat types:
Low-Complexity DNA (e.g. ATATATATACATA…)
Microsatellite repeats (a1…ak)N where k ~ 3-6
(e.g. CAGCAGTAGCAGCACCAG)
Transposons
SINE (Short Interspersed Nuclear Elements)
e.g., ALU: ~300-long, 106 copies
LINE (Long Interspersed Nuclear Elements)
~4000-long, 200,000 copies
LTR retroposons (Long Terminal Repeats (~700 bp) at each end)
cousins of HIV
Gene Families genes duplicate & then diverge (paralogs)
Recent duplications ~100,000-long, very similar copies

33. Sequencing and Fragment Assembly
AGTAGCACAGACTACGACGAGACGATCGTGCGAGCGACGGCGTAGTGTGCTGTACTGTCGTGTGTGTGTACTCTCCT
3x109 nucleotides
50% of human DNA is composed of repeats
Error!
Glued together two distant regions

34. What can we do about repeats?
Two main approaches:
Cluster the reads
Link the reads

35. What can we do about repeats?
Two main approaches:
Cluster the reads
Link the reads

36. What can we do about repeats?
Two main approaches:
Cluster the reads
Link the reads

37. Sequencing and Fragment Assembly
AGTAGCACAGACTACGACGAGACGATCGTGCGAGCGACGGCGTAGTGTGCTGTACTGTCGTGTGTGTGTACTCTCCT
3x109 nucleotides A R B
ARB, CRD or
ARD, CRB ? C R D

38. Sequencing and Fragment Assembly
AGTAGCACAGACTACGACGAGACGATCGTGCGAGCGACGGCGTAGTGTGCTGTACTGTCGTGTGTGTGTACTCTCCT
3x109 nucleotides

39. Strategies for whole-genome sequencing
Hierarchical – Clone-by-clone
Break genome into many long pieces
Map each long piece onto the genome
Sequence each piece with shotgun
Example: Yeast, Worm, Human, Rat
Online version of (1) – Walking
Start sequencing each piece with shotgun
Construct map as you go
Example: Rice genome
Whole genome shotgun
One large shotgun pass on the whole genome
Example: Drosophila, Human (Celera),
Neurospora, Mouse, Rat, Dog

40. Hierarchical Sequencing

41. Hierarchical Sequencing Strategy
a BAC clone
map
genome
Obtain a large collection of BAC clones
Map them onto the genome (Physical Mapping)
Select a minimum tiling path
Sequence each clone in the path with shotgun
Assemble
Put everything together

42. Methods of physical mapping
Goal:
Make a map of the locations of each clone relative to one another
Use the map to select a minimal set of clones to sequence
Methods:
Hybridization
Digestion

43. 1. Hybridization p1 pn
Short words, the probes, attach to complementary words
Construct many probes
Treat each BAC with all probes
Record which ones attach to it
Same words attaching to BACS X, Y  overlap

44. Hybridization – Computational Challenge
p1 p2 …………………….pm
Matrix:
m probes  n clones
(i, j): 1, if pi hybridizes to Cj
0, otherwise
Definition: Consecutive ones matrix
1s are consecutive in each row & col
Computational problem:
Reorder the probes so that matrix is in consecutive-ones form
Can be solved in O(m3) time (m > n)
0 0 1 …………………..1
C1 C2 ……………….Cn
1 1 0 …………………..0
1 0 1…………………...0
pi1pi2…………………….pim
……………..0
……………..0
……………..0
Cj1Cj2 ……………….Cjn
………
………

45. Hybridization – Computational Challenge
pi1pi2………………………………….pim
pi1pi2…………………….pim
……………..0
……………..0
……………..0
Cj1Cj2 ……………….Cjn
Cj1Cj2 ……………….Cjn
………
………
If we put the matrix in consecutive-ones form,
then we can deduce the order of the clones
& which pairs of clones overlap

46. Hybridization – Computational Challenge
p1 p2 …………………….pm
Additional challenge:
A probe (short word) can hybridize in many places in the genome
Computational Problem:
Find the order of probes that implies the minimal probe repetition
Equivalent: find the shortest string of probes such that each clone appears as a substring
APX-hard
Solutions:
Greedy, probabilistic, lots of manual curation
0 0 1 …………………..1
C1 C2 ……………….Cn
1 1 0 …………………..0
1 0 1…………………...0

47. 2. Digestion Restriction enzymes cut DNA where specific words appear
Cut each clone separately with an enzyme
Run fragments on a gel and measure length
Clones Ca, Cb have fragments of length { li, lj, lk }  overlap
Double digestion:
Cut with enzyme A, enzyme B, then enzymes A + B

48. Online Clone-by-clone The Walking Method

49. The Walking Method
Build a very redundant library of BACs with sequenced clone-ends (cheap to build)
Sequence some “seed” clones
“Walk” from seeds using clone-ends to pick library clones that extend left & right

50. Walking: An Example

51. Advantages & Disadvantages of Hierarchical Sequencing
ADV. Easy assembly
DIS. Build library & physical map;
redundant sequencing
Whole Genome Shotgun (WGS)
ADV. No mapping, no redundant sequencing
DIS. Difficult to assemble and resolve repeats
The Walking method – motivation
Sequence the genome clone-by-clone without a physical map
The only costs involved are:
Library of end-sequenced clones (cheap)
Sequencing

52. Walking off a Single Seed
Low redundant sequencing
Many sequential steps

53. Walking off a single clone is impractical
Cycle time to process one clone: 1-2 months
Grow clone
Prepare & Shear DNA
Prepare shotgun library & perform shotgun
Assemble in a computer
Close remaining gaps
A mammalian genome would need 15,000 walking steps !

54. Walking off several seeds in parallel
Efficient
Inefficient
Few sequential steps
Additional redundant sequencing
In general, can sequence a genome in ~5 walking steps,
with <20% redundant sequencing

55. Using Two Libraries
Most inefficiency comes from closing a small gap with a much larger clone
Solution: Use a second library of small clones

56. Some Terminology
insert a fragment that was incorporated in a
circular genome, and can be copied
(cloned)
vector the circular genome (host) that
incorporated the fragment
BAC Bacterial Artificial Chromosome, a type
of insert–vector combination, typically
of length kb
read a long word that comes out of
a sequencing machine
coverage the average number of reads (or
inserts) that cover a position in the
target DNA piece
shotgun the process of obtaining many reads
sequencing from random locations in DNA, to
detect overlaps and assemble

57. Whole Genome Shotgun Sequencing
cut many times at random
plasmids (2 – 10 Kbp)
forward-reverse paired reads
known dist
cosmids (40 Kbp)
~500 bp
~500 bp

58. Fragment Assembly (in whole-genome shotgun sequencing)

59. We need to use a linear-time algorithm
Fragment Assembly
Given N reads…
Where N ~ 30 million…
We need to use a linear-time algorithm

60. Steps to Assemble a Genome
Some Terminology
read a long word that comes
out of sequencer
mate pair a pair of reads from two ends
of the same insert fragment
contig a contiguous sequence formed
by several overlapping reads
with no gaps
supercontig an ordered and oriented set
(scaffold) of contigs, usually by mate
pairs
consensus sequence derived from the
sequene multiple alignment of reads
in a contig
1. Find overlapping reads
2. Merge some “good” pairs of reads into longer contigs
3. Link contigs to form supercontigs
4. Derive consensus sequence
..ACGATTACAATAGGTT..

61. 1. Find Overlapping Reads
(read, pos., word, orient.)
aaactgcag
aactgcagt
actgcagta …
gtacggatc
tacggatct
gggcccaaa
ggcccaaac
gcccaaact
ctgcagtac
acggatcta
ctactacac
tactacaca
(word, read, orient., pos.)
aaactgcag
aactgcagt
acggatcta
actgcagta
cccaaactg
cggatctac
ctactacac
ctgcagtac
gcccaaact
ggcccaaac
gggcccaaa
gtacggatc
tacggatct
tactacaca
aaactgcagtacggatct
aaactgcag
aactgcagt …
gtacggatct
tacggatct
gggcccaaactgcagtac
gggcccaaa
ggcccaaac
actgcagta
ctgcagtac
gtacggatctactacaca
gtacggatc
ctactacac
tactacaca

62. 1. Find Overlapping Reads
Find pairs of reads sharing a k-mer, k ~ 24
Extend to full alignment – throw away if not >98% similar
TACA
TAGT ||
TAGATTACACAGATTAC
T GA
TAGA
| ||
|||||||||||||||||
TAGATTACACAGATTAC
Caveat: repeats
A k-mer that occurs N times, causes O(N2) read/read comparisons
ALU k-mers could cause up to 1,000,0002 comparisons
Solution:
Discard all k-mers that occur “too often”
Set cutoff to balance sensitivity/speed tradeoff, according to genome at hand and computing resources available

63. 1. Find Overlapping Reads
Create local multiple alignments from the overlapping reads
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAG TTACACAGATTATTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAG TTACACAGATTATTGA
TAGATTACACAGATTACTGA

64. 1. Find Overlapping Reads
Correct errors using multiple alignment
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTATTGA
TAG-TTACACAGATTATTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAG-TTACACAGATTACTGA
TAG-TTACACAGATTATTGA
insert A
correlated errors—
probably caused by repeats
 disentangle overlaps
replace T with C
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
TAGATTACACAGATTACTGA
In practice, error correction removes
up to 98% of the errors
TAG-TTACACAGATTATTGA
TAG-TTACACAGATTATTGA

65. 2. Merge Reads into Contigs
Overlap graph:
Nodes: reads r1…..rn
Edges: overlaps (ri, rj, shift, orientation, score)
Reads that come
from two regions of
the genome (blue
and red) that contain
the same repeat
Note:
of course, we don’t
know the “color” of
these nodes

66. 2. Merge Reads into Contigs
repeat region
Unique Contig
Overcollapsed Contig
We want to merge reads up to potential repeat boundaries

67. 2. Merge Reads into Contigs
repeat region
Ignore non-maximal reads
Merge only maximal reads into contigs

68. 2. Merge Reads into Contigs
Remove transitively inferable overlaps
If read r overlaps to the right reads r1, r2, and r1 overlaps r2, then (r, r2) can be inferred by (r, r1) and (r1, r2)

69. 2. Merge Reads into Contigs

70. 2. Merge Reads into Contigs
repeat boundary???
sequencing error b a … b a
Ignore “hanging” reads, when detecting repeat boundaries

71. Overlap graph after forming contigs
Unitigs:
Gene Myers, 95

72. Repeats, errors, and contig lengths
Repeats shorter than read length are easily resolved
Read that spans across a repeat disambiguates order of flanking regions
Repeats with more base pair diffs than sequencing error rate are OK
We throw overlaps between two reads in different copies of the repeat
To make the genome appear less repetitive, try to:
Increase read length
Decrease sequencing error rate
Role of error correction:
Discards up to 98% of single-letter sequencing errors
decreases error rate
 decreases effective repeat content
 increases contig length

73. 2. Merge Reads into Contigs
Insert non-maximal reads whenever unambiguous

74. 3. Link Contigs into Supercontigs
Normal density
Too dense
 Overcollapsed
Inconsistent links
 Overcollapsed?

75. 3. Link Contigs into Supercontigs
Find all links between unique contigs
Connect contigs incrementally, if  2 links
supercontig
(aka scaffold)

76. 3. Link Contigs into Supercontigs
Fill gaps in supercontigs with paths of repeat contigs

77. 4. Derive Consensus Sequence
TAGATTACACAGATTACTGA TTGATGGCGTAA CTA
TAGATTACACAGATTACTGACTTGATGGCGTAAACTA
TAG TTACACAGATTATTGACTTCATGGCGTAA CTA
TAGATTACACAGATTACTGACTTGATGGCGTAA CTA
TAGATTACACAGATTACTGACTTGATGGGGTAA CTA
TAGATTACACAGATTACTGACTTGATGGCGTAA CTA
Derive multiple alignment from pairwise read alignments
Derive each consensus base by weighted voting
(Alternative: take maximum-quality letter)

78. Some Assemblers PHRAP Celera Arachne Phusion Euler
Early assembler, widely used, good model of read errors
Overlap O(n2)  layout (no mate pairs)  consensus
Celera
First assembler to handle large genomes (fly, human, mouse)
Overlap  layout  consensus
Arachne
Public assembler (mouse, several fungi)
Phusion
Overlap  clustering  PHRAP  assemblage  consensus
Euler
Indexing  Euler graph  layout by picking paths  consensus

79. Quality of assemblies
Celera’s assemblies of human and mouse

80. Quality of assemblies—mouse

81. Quality of assemblies—mouse
Terminology: N50 contig length
If we sort contigs from largest to smallest, and start
Covering the genome in that order, N50 is the length
Of the contig that just covers the 50th percentile.

82. Quality of assemblies—rat

83. History of WGA 1982: -virus, 48,502 bp 1995: h-influenzae, 1 Mbp
1997
1982: -virus, 48,502 bp
1995: h-influenzae, 1 Mbp
2000: fly, 100 Mbp
2001 – present
human (3Gbp), mouse (2.5Gbp), rat*, chicken, dog, chimpanzee, several fungal genomes
Let’s sequence the human genome with the shotgun strategy
That is impossible, and a bad idea anyway
Phil Green
Gene Myers

84. Genomes Sequenced