Mechanisms of Precise Genome Editing using ...

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1 2 3 4 5 6

Mechanisms of Precise Genome Editing using Oligonucleotide Donors

Yinan Kan1, Brian Ruis2, Taylor Takasugi3 and Eric A. Hendrickson2, 4

7

2

8

Minnesota Medical School, Minneapolis, MN 55455

Department of Biochemistry, Molecular Biology, and Biophysics, University of

9 10

1

11

Avenue Louis Pasteur, Room 238, Boston, MA 02115.

Current Address:

Department of Genetics, New Research Building, 77

12 13

3

14

333 Cedar St., New Haven, CT 06510.

Current Address:

Department of Medicine, Yale University Medical School,

15 16

4

17

Minnesota Medical School, 6-155 Jackson Hall, 321 Church St., SE.

18

Minneapolis, MN 55455. E-mail: [email protected].

Corresponding author: Eric A. Hendrickson, BMBB Department, University of

19

1

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

20

Abstract

21

The use of programmable meganucleases is transforming genome editing and

22

functional genomics.

23

genomic lesions could be introduced in vivo with unprecedented ease.

24

presence of homology donors, these lesions facilitate high-efficiency precise

25

genome editing (PGE) via homology-directed repair (HDR) pathways.

26

However, the identity and hierarchy of the HDR (sub)pathways leading to the

27

formation of PGE products remain elusive.

28

blue fluorescent protein conversion system to systematically characterize

29

oligodeoxynucleotide (ODN)-mediated PGE using Cas9 and its nickase

30

variants in human cells. We demonstrate that, unlike double-stranded DNA

31

(dsDNA) donors with central heterologies, ODNs generated short conversion

32

tracts with Gaussian-like distributions. Interestingly, single nick-induced PGE

33

using ODN donors produced conversion tracts biased either mostly uni- or

34

bi-directional depending on the relative strandedness of the ODNs and the nick.

35

Moreover, the ODNs were physically incorporated into the genome only in the

36

bidirectional, but not in the unidirectional, conversion pathway.

37

presence of double-stranded genomic lesions, the unidirectional conversion

38

pathway was preferentially utilized even though the knock-in mutation could

39

theoretically have been converted by both pathways.

40

suggest that ODN-mediated PGE utilizes synthesis-dependent strand

41

annealing and single-stranded DNA incorporation pathways.

42

pathways generate short conversion tracts with Gaussian-like distributions.

43

Although synthesis-dependent strand annealing is preferentially utilized, our

44

work unequivocally establishes the existence of a single-stranded DNA

45

incorporation pathway in human cells.

46

HDR-mediated gene conversion and establishes guidelines for PGE in human

47

cells.

CRISPR/Cas9 was developed such that targeted

2

In the

Here we established a green to

In the

Collectively, our results

Both of these

This work extends the paradigms of

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

48

Introduction

49

Genome editing is the intentional alteration of the genetic information in living

50

cells or organisms. Since Clustered Regularly Interspaced Short Palindromic

51

Repeats/CRISPR-associated 9 (CRISPR/Cas9) (Jinek et al. 2012) was

52

repurposed for genome editing (Cong et al. 2013; DiCarlo et al. 2013; Jinek et

53

al. 2013), the speed of CRISPR methodology is quickly bridging the genotype

54

and phenotype worlds and facilitating high-throughput reverse genetic studies

55

(Wright et al. 2016). In the CRISPR age, targeted genomic lesions can be

56

introduced with unprecedented ease, which facilitate either high-efficiency

57

gene disruption by non-homologous end joining (NHEJ) or, in the presence of

58

donor DNA, PGE by HDR (Carroll 2014).

59

genotype can be expeditiously generated for most genetically-tractable

60

organisms (Bassett et al. 2013; DiCarlo et al. 2013; Liu et al. 2014; Yang et al.

61

2014; Reardon 2016), and within one round of subcloning of cultured cells

62

(Ran et al. 2013b; Byrne et al. 2014). Although HDR is the more desirable

63

pathway for genome editing and gene therapy, its activity is much lower than

64

NHEJ and dependent on the cell cycle status in human cells (Mao et al. 2008b;

65

Mao et al. 2008a; Lin et al. 2014; Orthwein et al. 2015). Thus, marker-free

66

PGE still requires the laborious screening of hundreds of subclones, especially

67

in hard-to-transfect cells or those with low HDR activity or limited tolerance of

68

genomic lesions. Moreover, bi-allelic and multiplexed PGE is still challenging

69

in human cells.

70

Research models of the desired

Complicating our understanding of PGE is the fact that HDR has multiple

71

sub-pathways in eukaryotic cells (San Filippo et al. 2008).

72

sub-pathways can lead to PGE without significantly sacrificing genomic

73

stability: the double-strand break repair (DSBR, aka, Holliday junction

74

resolution) pathway (Orr-Weaver et al. 1981; Orr-Weaver and Szostak 1983),

75

Holliday junction dissolution (Wu and Hickson 2003; Bizard and Hickson 2014;

3

Four of these

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

76

Swuec and Costa 2014), synthesis-dependent strand annealing (SDSA)

77

(Strathern et al. 1982; Hastings 1988; Larocque and Jasin 2010) and

78

single-strand DNA incorporation (ssDI, also sometimes referred to as

79

single-strand assimilation) (Radecke et al. 2006b; Storici et al. 2006; Davis and

80

Maizels 2014) pathways (Supplemental Fig. S1).

81

fraction of HDR events leading to the conversion of desired knock-in mutations

82

using exogenous homology donors. Importantly, the identity and hierarchy of

83

usage of the HDR sub-pathways leading to the formation of PGE products

84

remains a knowledge barrier that hinders the improvement of PGE.

PGE is defined by the

85

In a previous study we demonstrated that in human somatic cells the

86

introduction of large knock-in mutations with dsDNA donors (including

87

transfected plasmids or viruses with dsDNA intermediates) preferentially

88

engages the DSBR sub-pathway for PGE (Kan et al. 2014). Although ODNs

89

probably do not serve as natural HDR donors, many laboratories have

90

reported that PGE can be routinely obtained by exogenously transfecting ODN

91

donors into cells (Chen et al. 2015; Richardson et al. 2016). Since ODN

92

donors are likely unable to physically form Holliday junctions and therefore

93

cannot engage DSBR, they must perforce utilize some form of the SDSA or

94

ssDI pathways during PGE (Storici et al. 2006; Davis and Maizels 2014).

95

the absence of a targeted meganuclease like Cas9, the ODN donors may use

96

spontaneously occurring genomic lesions in order to perform PGE. Indeed, it

97

was proposed that ODNs could be incorporated into the gaps generated by

98

nucleotide excision repair (Faruqi et al. 2000; Kuan and Glazer 2004) or

99

lagging strand synthesis during DNA replication (Ferrara and Kmiec 2004; Wu

100

et al. 2005; Huen et al. 2006), although the specific mechanisms are still

101

disputed (Suzuki 2008; Jensen et al. 2011).

102

models involve the physical incorporation of the ODNs into the genome via an

103

ssDI-like mechanism; a prediction that was later supported by experiments

104

carried out by Radecke et al. (Radecke et al. 2006b). 4

In

Interestingly, both of these

Confusingly, however,

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

105

the same group of authors also demonstrated that ODNs were not physically

106

incorporated into the genome during double-strand break (DSB)-induced PGE,

107

suggesting the existence of an alternative mechanism(s) (Radecke et al.

108

2006a).

109

single-strand nicks, it was proposed by Davis and Maizels that certain forms of

110

the SDSA and the ssDI pathways could be utilized depending on the

111

strandedness of the donor ODNs (Davis and Maizels 2011; Davis and Maizels

112

2014), a hypothesis that was supported by recent work from the Corn

113

laboratory (Richardson et al. 2016).

114

conversion tracts and hierarchy of these pathways have remained elusive.

Finally, in the presence of meganuclease-induced targeted

115

5

However, the exact mechanisms,

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

116

Results

117

The enhanced green fluorescent protein (EGFP) to blue fluorescent

118

protein (BFP) conversion system

119

To

120

meganuclease-induced PGE using ODN donors, we established the EGFP to

121

BFP conversion system (Fig. 1A).

122

sequence similarity of EGFP and BFP.

123

mutations into the chromophore domain, EGFP can be completely converted

124

into BFP (Katada et al. 2008).

125

adeno-associated virus (rAAV)-mediated PGE (Khan et al. 2011; Kan et al.

126

2014), we introduced the CMV-EGFP-pA expression cassette into the

127

hypoxanthine

128

chromosome of human HCT116 cells, in both sense (S) and antisense (AS)

129

directions with respect to the direction of the HPRT1 gene (Supplemental Fig.

130

S2A, B).

131

expression and the inactivation of the HPRT1 gene. After rAAV infection, the

132

HPRT1-negative cells were enriched using 6-thioguanine selection, and

133

individual subclones with bright EGFP expression were screened using

134

designated primers (Supplemental Fig. S2A, B).

135

precisely knocked into the HPRT1 gene in 1 out of 4 subclones in the sense

136

orientation and 2 out of 4 subclones in the antisense orientation (Supplemental

137

Fig. S2C, D). One individual subclone from each orientation was designated

138

as HPRT1-EGFP (S) and (AS) cell lines, respectively, and used for

139

subsequent studies. Targeted genomic lesions such as nicks and DSBs were

140

subsequently introduced into these reporter cell lines within the chromophore

141

sequence using Cas9 or nCas9 from S. pyogenes and sgRNAs in both S and

142

AS orientations with respect to EGFP (Fig. 1A). In the presence of ODN

143

donors bearing the SH mutations (ACCTAC to TCTCAT), EGFP could

systematically

investigate

the

molecular

mechanisms

of

This system takes advantage of the By introducing T65S and Y66H

To this end, using recombinant

phosphoribosyltransferase 1 (HPRT1) locus

on

the X

Targeted integration in either direction results in mono-allelic EGFP

6

The EGFP cassette was

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

144

efficiently be converted into BFP, which generated distinguishable spectra

145

under flow cytometry (Supplemental Fig. S3B, C).

146 147

ODNs stimulate efficient PGE in the presence of genomic lesions

148

We first compared the efficiency of ODN-mediated PGE using nCas9 with

149

ODNs (BFP_S160 and BFP_AS160, see Supplemental Fig. S10 for more

150

details) and sgRNAs in both S and AS orientations with respect to EGFP.

151

transfecting the HPRT1-EGFP cell lines with the nCas9 and sgRNA

152

expression vectors and ODN donors all in a DNA format, we could routinely

153

induce efficient EGFP to BFP conversion as quantitated using flow cytometry

154

(Fig. 1; Supplemental Fig. S3). In contrast, the omission of the Cas9 and/or

155

sgRNA resulted in 7 nt)

574

resection of the 3’-end was required for PGE to occur and we believe that

575

these two observations are connected given the sharp drop-off in the SDSA

576

conversion tracts (Fig. 2A, B).

577

that double-strand lesions in general loosen the local chromatin architecture

578

more than single-strand nicks and thus permit relevant co-factors (such as

579

resection nucleases) easier access to the 3’-end, which ultimately facilitates

580

more vigorous homology searches.

581

The only instance where

If this exception is illustrative, it may suggest

In our nick-induced PGE experiments, no significant strand bias for either

582

the nick or the ODN donors was observed (Fig. 1B).

583

were consistent with a previous report using zinc-finger nickases at three

584

independent chromosomal loci (Ramirez et al. 2012) but inconsistent with a

585

more recent one (Davis and Maizels 2014).

586

explained by the fact that the recent report employed ODN donors with a large

587

(17 bp) heterology flanking the genomic lesion (Davis and Maizels 2014).

588

discussed above, a sizable heterology on both sides of the genomic lesion

589

could strongly favor the use of ssDI as a bi-directional gene conversion

590

pathway.

591

resection of at least 8 to 9 nt would be required and that likely occurs at a much

592

lower frequency.

593

transactions such as transcription and DNA replication are unlikely to have a

594

major influence on PGE mediated by nicks. With that said, it is important to

595

note that while no strand-specific biases were noted in any of our experiments,

These observations

The latter difference might be

As

In contrast, in order to be converted by the SDSA pathway, 3’

Collectively, these observations suggest that strand-specific

22

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

596

a significant 2- to 4-fold higher frequency of PGE was noted for the BFP

597

reporter in the anti-sense orientation than in the sense orientation (Fig. 1 and

598

Supplemental Fig. S3). The reason for this bias is not completely clear, but it

599

is unlikely to be due to conflicting transcription between the EGFP reporter and

600

the endogenous HPRT1 locus because EGFP expression was very high in

601

these cells. Indeed, we believe the bias was technical (and not biological) in

602

nature since the higher EGFP (and consequently BFP) expression may have

603

simply allowed us to more easily isolate correctly targeted cells.

604

also note that a strand bias was observed when PGE was mediated by nicks

605

and same sense ODN donors in RPE+hTERT cells (Supplemental Fig. S8B).

606

As discussed previously, we do not believe that this is related to transcription

607

nor DNA replication issues, but to the fact that these cells are MMR proficient,

608

which is especially inhibitory to the strand annealing step required for ssDI.

Finally, we

609

PAM-in paired-nickases are significantly less effective in producing

610

NHEJ-related mutations than their PAM-out counterparts, which has mainly

611

been attributed to the steric hindrance of the nCas9 proteins in the PAM-in

612

configuration and/or the displacement loops formed the by sgRNAs (Ran et al.

613

2013a; Cho et al. 2014; Shen et al. 2014).

614

additional or alternative explanation (Fig. 4A, 5A): PAM-out paired-nickases

615

generate 5’-overhangs that are subject to exonuclease resection (Symington

616

and Gautier 2011).

617

normally engage the error-prone NHEJ pathway and produce deletions in

618

between.

619

may remain largely as separated nicks (Fig. 4B, 5B), which may be precisely

620

repaired by standard single-strand nick repair without engaging the NHEJ

621

pathway.

622

at a comparable efficiency to their PAM-out counterparts (Fig. 1B), at least

623

when the PAM sequences are placed far enough apart from each other to

624

avoid steric hindrance.

Our results may provide an

The resection creates a double-strand gap that will

In contrast, the 3’ overhangs produced by PAM-in paired-nickases

Importantly, however, the PAM-in paired-nickases can induce PGE

Thus, we propose that PAM-in paired-nickases are 23

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

625

less efficient in NHEJ-mediated gene disruption because the 3’ overhangs

626

rarely form double-strand gaps due to the lack of 3’ to 5’ resection (Symington

627

and Gautier 2011).

628

often used for PGE, they may actually be advantageous because they may

629

induce similar levels of HDR with less NHEJ mutations compared to their

630

PAM-out counterparts.

631

efficient generation of short 3’ overhangs with PAM-out sgRNAs, minimizing

632

the effect of steric hindrance (Nishimasu et al. 2014).

Consequently, although PAM-in paired nickases are not

The use of the Cas9 N863A variant further allows the

633

Although paired-nickases induced PGE with a higher frequency compared

634

to a single nickase (Fig. 1B), we noticed that paired-nickases (in both PAM

635

configurations) occasionally produced imprecise HDR products using ODN

636

donors (Supplemental Tables S6 to S9).

637

contained NHEJ-like mutations near the position of the distal nick with respect

638

to the knock-in mutations. Since a single nickase can also generate NHEJ

639

mutations (Davis and Maizels 2011; Davis and Maizels 2014), we propose that

640

the imprecise HDR was generated by the repeated nicking of the distal nickase

641

in the PGE products.

642

the proximal nicks because, in our system, the conversion of the knock-in

643

mutations would destroy the binding site of the proximal nickase and prevent

644

further nicking in the PGE products. If this hypothesis is correct, an important

645

guideline of ODN-mediated PGE would be to introduce an additional silent

646

mutation in the PAM sequence of the ODN donors to prevent the further

647

binding of Cas9 or nCas9 in the PGE products. Alternatively, these nicks

648

might be converted to frank DSBs, which through canonical end joining might

649

yield NHEJ-like mutations.

Most of the imprecise products

These mutations were not found near the position of

650

Our conversion tract data also provides insight into a recent paradox:

651

although SDSA is the more efficient form of meganuclease-induced HDR (Li et

652

al. 2001; Heyer et al. 2010), the majority of the PGE products are actually

653

generated by the DSBR pathway when dsDNA donors with long central 24

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

654

heterologies are employed (Li and Baker 2000; Li et al. 2001; Langston and

655

Symington 2004; Kan et al. 2014). Our results and other’s demonstrate that

656

SDSA is apparently a short-tract gene conversion pathway using chromosomal

657

(Elliott et al. 1998; Larocque and Jasin 2010) and ODN donors (Fig. 2A, B).

658

Also, the Gaussian-like nature of the associated conversion tracts makes it

659

extremely inefficient in producing gene conversions longer than 100 bp (Fig.

660

2A, B).

661

engage

662

meganuclease-induced

663

generated unidirectional long-tract gene conversion products (Elliott et al. 1998;

664

Larocque and Jasin 2010), which were believed to be produced by

665

break-induced replication (BIR) (Borts and Haber 1987; Kraus et al. 2001;

666

Llorente et al. 2008). In the case of PGE, however, BIR using exogenous

667

homology donors leads to the formation of chromosome:donor fusions and

668

severely compromises genomic stability (Borts and Haber 1987; Kraus et al.

669

2001; Llorente et al. 2008). In contrast, our previous work demonstrated that

670

the DSBR pathway is a second (and precise) long-tract gene conversion

671

pathway (Kan et al. 2014), which generates bi-directional conversion tracts

672

with a linear distribution.

673

SDSA is the more efficient HDR pathway for short-tract gene-conversion, the

674

DSBR pathway is the predominant pathway of PGE using dsDNA donors with

675

long central heterologies.

Thus, dsDNA donors with long central heterologies would perforce a

long-tract

gene

HDR

conversion

using

pathway.

chromosomal

donors

Notably, occasionally

Collectively, these results indicate that although

676

dsDNA donors can mediate robust PGE. We can routinely achieve about

677

20% marker-free PGE using Cas9-2A-GFP with associated FACS enrichment

678

(Duda et al. 2014) and circular dsDNA donors with long central heterologies

679

(data not shown).

680

should be utilized in the presence of DSBs and/or paired-nicks for converting

681

large knock-in mutations (Fig. 7). One of the reasons that these donors work

682

so well is that they may have a longer half-life than ODN donors, which better

As a practical guideline, we propose that circular dsDNA

25

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

683

coincides with the kinetics of the Cas9 expressed in a DNA format.

684

contrast, ODN donors should be utilized for converting small modifications.

685

Although ODN donors are optimally used for introducing SNPs, they can also

686

be used to introduce more complex genomic lesions by producing slightly

687

longer conversion tracts.

688

knock-in mutation(s) needs to be placed within the effective conversion zones

689

of the SDSA or ssDI pathways, or it will not be incorporated into the genome

690

(Fig. 7).

691

accommodate the shorter half-life of ODN donors and increase the efficiency

692

of PGE.

In

Regardless, what is critical is that the desired

Cas9 expressed in mRNA or protein formats may be used to

693

Finally, our results demonstrated that the ODN donors are not physical

694

incorporated into the genome in the SDSA pathway, making this pathway

695

particularly valuable for agricultural engineering.

696

livestock containing CRISPR-mediated gene disruption are generally not

697

categorized as genetically modified organisms (GMOs), PGE using exogenous

698

HDR donors is under more stringent regulatory scrutiny (Wolt et al. 2016). An

699

empirical distinction lies in whether the engineering process leads to the

700

incorporation of foreign DNA into the genome (Wolt et al. 2016).

701

established that when an nCas9 and ODNs complementary to the strand of the

702

nick are used in combination, the genomic modification is introduced via the

703

endogenous DNA repair process of SDSA, whereas the ODN donors merely

704

serve as repair templates (Fig. 2, 4, 6). These findings extend the scope of

705

non-GMO plants and livestock to ODN-mediated PGE.

26

Although plants and

We

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

706

Methods

707

Nucleotide sequences

708

All sgRNA targets, ODN donors, primers and the relevant plasmid sequences

709

can be found in Supplemental Fig. S10.

710 711

Cell culture

712

All cell lines utilized in this study were purchased from the American Type

713

Culture Collection.

714

McCoy’s 5A medium supplemented with 10% FBS, 1% L-glutamine, 1%

715

penicillin/streptomycin.

716

Dulbecco’s modified Eagle medium supplemented with 10% FBS, and 1%

717

penicillin/streptomycin. All cells were grown with 5% CO2 at 37 oC.

The human HCT116 and DLD-1 cell lines were cultured in

The human RPE+hTERT cell line was cultured in

718 719

The HPRT1-EGFP cell lines

720

The rAAV EGFP knock-in vectors were constructed using an unpublished

721

method (Kan et al., manuscript in preparation).

722

cassette was amplified from EGFP-N2 (Clontech), and the homology arms

723

flanking

724

(Supplementary Fig. S10).

725

were ligated into a modified version of the pAAV-MCS vector in both sense and

726

antisense orientations with respect to HPRT1. rAAV packaging and infections

727

were performed as described (Khan et al. 2011).

728

were seeded into 10 cm tissue culture dishes and selected with 5 μg/mL 6-TG

729

for 14 days.

730

under a fluorescence microscope, and subsequently screened by PCR using

731

the indicated primers (Supplemental Fig. S2A, B). One of the targeted clones

732

with EGFP in either sense or antisense directions in the HPRT1 locus were

733

flow sorted for high EGFP expression using a FACSAria II cell sorter (BD

HPRT1

exon

3

were

amplified

Basically, the CMV-EGFP-pA

using

designated

primers

The CMV-EGFP-pA cassette and homology arms

The infected HCT116 cells

Individual colonies were initially scanned for EGFP expression

27

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

734

Biosciences) and used for subsequent studies.

735 736

The EGFP to BFP conversion system

737

The EGFP reporter cells were seeded at ~50% confluency. The next day, 5 x

738

105 cells were transfected with a Cas9 or nCas9 expression plasmid (10 μg;

739

#41815 and #41816, respectively, Addgene), the MLM3636 plasmid containing

740

the designated sgRNA expression cassette (10 μg; #43860, Addgene) and the

741

relevant ODNs (10 μg) using a Neon Transfection System (Invitrogen).

742

paired-nickases, cells were transfected with 7.5 μg of each sgRNA plasmid,

743

the Cas9 expression plasmid and ODNs. All transfections were performed

744

using 100 μL tips under elevated conditions compared to the manufacturer’s

745

protocol: 1530V, a 10 msec pulse width, and 3 pulses.

746

experiment, cells were transfected using ODNs without flanking SNPs

747

(Supplementary Fig. 10), and the percentage of BFP-positive cells were

748

quantitated 2 days after transfection using a LSRFortessa cell analyzer (BD

749

Biosciences).

750

using ODNs containing flanking SNPs.

751

were combined, cultured for 2 days and sorted for BFP expression using a

752

FACSAria II cell sorter (BD Biosciences).

For

For the PGE efficiency

For the conversion tracts experiment, cells were transfected Cells from 5 individual transfections

753 754

Conversion tracts analysis

755

The BFP-positive cells were single-cell subcloned into 96-well-plates at a

756

concentration of 3 to 10 cells per well.

757

trypsinized, transferred into new 96-well plates and grown to confluency.

758

Genomic DNA was prepared using DirectPCR Lysis Reagent (Viagene).

759

BFP fragments containing all the potential SNPs were amplified and confirmed

760

by PCR using primers BFP_EF X BFP_ER and BFP_CF X BFP_ER,

761

respectively.

762

purification kit.

14 days later, single colonies were

The

The PCR products were purified using a Qiaquick PCR The retention of vector-borne SNPs was analyzed by Sanger 28

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

763

sequencing.

764 765

Statistics

766

Kolmogorov-Smirnov tests were performed to determine the degree of

767

symmetry around the central dinucleotides of the ODN donors for SNP

768

retention curves induced by single-nicks. All reads from Sanger and Illumina

769

sequencing were randomly divided into three groups.

770

frequency of all SNPs with approximately equal distance to the central

771

dinucleotides

772

Kolmogorov-Smirnov equations in pairs.

773

the corresponding graphs.

774

the distributions around the Y-axis, which is the central heterology of the ODN

775

donors.

was

compiled

in

each

group

and

The retention

entered

into

the

The resultant p-value is shown on

The p-value reflects the degree of symmetry of

776 777

The PIGA conversion system

778

0.5 million DLD-1 and RPE+hTERT cells were transfected with 15 μg

779

PIGA_KO ODNs (Supplemental Fig. S6A, S8A, S9) and 15 μg Cas9

780

D10A-2A-mCherry with the respective S or AS sgRNA expression cassette in

781

one backbone (adapted from PX461).

782

each sgRNA, recovered for 14 days, stained with the FLAER reagent

783

(Pinewood Scientific Services) at a concentration of 5 X 10-9 M and FACS

784

sorted for PIGA negativity.

785

expression were collected for S and AS sgRNA, respectively, using a

786

non-stringent gate (Supplemental Fig. S7).

787

of HDR and NHEJ events and some wild type cells. Then the genomic DNA

788

was prepared using DirectPCR lysis (Viagen), and the target locus was

789

amplified using flanking Nextera compatible primers (NextF & NextR,

790

Supplemental Fig. S10). The amplicons were gel purified and sequenced

791

using Nextera amplicon sequencing (paired-end 2 x 125 bp).

10 transfections were combined for

5.6% and 6.5% of the cells with the lowest PIGA

29

These cells contain the majority

The HDR

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

792

products were characterized as the reads containing the central GT

793

dinucleotide.

794

retention frequency of flanking SNPs in the HDR products versus the position

795

of the SNPs in reference to the GT dinucleotide.

The SNP retention curves were compiled by plotting the

796 797

The biotin incorporation assay

798

The biotin incorporation assay was performed as described (Radecke et al.

799

2006b) with minor modifications. The EGFP reporter cells were transfected

800

with internal biotin-labeled ODNs (BFP_S90_Biotin) and flow sorted as

801

described above. The genomic DNA from 1 x 105 BFP-positive cells was

802

prepared using a Puregene Cell kit (Gentra) with a 60 min centrifugation step

803

after isopropanol precipitation.

804

completion with XhoI and XbaI restriction enzymes (New England Biolabs).

805

The biotinylated DNA fragments were isolated using a Dynabeads Kilobase

806

BINDER kit (Life Technologies) according to manufacturer’s protocol, except

807

that all reagents were supplemented with 0.1% BSA, and two additional

808

washes using 0.1 M NaOH and 0.05 M NaCl at room temperature and one

809

more rinse with 95 oC water were performed to remove the non-covalently

810

linked genomic fragments.

811

detected with a 40-cycle PCR using Phusion Hot Start II High-Fidelity DNA

812

polymerase (Thermo Scientific).

813

Dynabeads purification was used as control in a 25-cycle reaction.

The genomic DNA was digested to

The biotinylated genomic fragments were

The genomic DNA preparation prior to

814 815

Author’s contributions

816

Y. K. and E. A. H. designed the study, analyzed the data and wrote the

817

manuscript. Y. K. performed the bulk of the experiments and T. T. and B. R.

818

assisted during the latter stages of the project.

819

30

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

820

Acknowledgements

821

We thank Drs. Feng Zhang, Keith Joung and George Church for sharing

822

plasmids through Addgene.

823

University of Minnesota Flow Cytometry Core for cell sorting.

824

supported by grants from the National Institutes of General Medical Sciences

825

(GM088351) and the National Cancer Institute (CA154461 and CA190492).

We thank Jason Motl and Nisha Shah at This work was

826 827

Competing Interests

828

E.A.H. declares that he is a member of the scientific advisory boards of

829

Horizon Discovery, Ltd. and Intellia Therapeutics, companies that specialize in

830

applying gene editing technology to basic research and therapeutics.

831

31

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

832 833

References

834

Balakrishnan L, Bambara RA. 2013. Flap endonuclease 1. Ann Rev Biochem

835

82: 119-138.

836

Bassett AR, Tibbit C, Ponting CP, Liu JL. 2013. Highly efficient targeted

837

mutagenesis of Drosophila with the CRISPR/Cas9 system. Cell Rep 4:

838

220-228.

839 840

Bizard AH, Hickson ID. 2014. The dissolution of double Holliday junctions. Cold Spring Harb Perspect Biol 6: a016477.

841

Bodnar AG, Ouellette M, Frolkis M, Holt SE, Chiu CP, Morin GB, Harley CB,

842

Shay JW, Lichtsteiner S, Wright WE. 1998. Extension of life-span by

843

introduction of telomerase into normal human cells. Science 279:

844

349-352.

845 846 847 848 849 850 851 852

Borts RH, Haber JE. 1987. Meiotic recombination in yeast: alteration by multiple heterozygosities. Science 237: 1459-1465. Byrne SM, Mali P, Church GM. 2014. Genome editing in human stem cells. Methods Enzymol 546: 119-138. Carroll D. 2014. Genome engineering with targetable nucleases. Ann Rev Biochem 83: 409-439. Chen F, Pruett-Miller SM, Davis GD. 2015. Gene editing using ssODNs with engineered endonucleases. Methods Mol Biol 1239: 251-265.

853

Chen TR, Hay RJ, Macy ML. 1983. Intercellular karyotypic similarity in

854

near-diploid cell lines of human tumor origins. Cancer Genet Cytogenet

855

10: 351-362.

856

Cho SW, Kim S, Kim JM, Kim JS. 2013. Targeted genome engineering in

857

human cells with the Cas9 RNA-guided endonuclease. Nat Biotechnol

858

31: 230-232.

859

Cho SW, Kim S, Kim Y, Kweon J, Kim HS, Bae S, Kim JS. 2014. Analysis of

32

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

860

off-target effects of CRISPR/Cas-derived RNA-guided endonucleases

861

and nickases. Genome Res 24: 132-141.

862

Cong L, Ran FA, Cox D, Lin S, Barretto R, Habib N, Hsu PD, Wu X, Jiang W,

863

Marraffini LA et al. 2013. Multiplex genome engineering using

864

CRISPR/Cas systems. Science 339: 819-823.

865 866

Davis L, Maizels N. 2011. DNA nicks promote efficient and safe targeted gene correction. PloS one 6: e23981.

867

Davis L, Maizels N. 2014. Homology-directed repair of DNA nicks via pathways

868

distinct from canonical double-strand break repair. Proc Natl Acad Sci U

869

S A 111: E924-932.

870

DiCarlo JE, Norville JE, Mali P, Rios X, Aach J, Church GM. 2013. Genome

871

engineering in Saccharomyces cerevisiae using CRISPR-Cas systems.

872

Nucleic Acids Res 41: 4336-4343.

873

Duda K, Lonowski LA, Kofoed-Nielsen M, Ibarra A, Delay CM, Kang Q, Yang Z,

874

Pruett-Miller SM, Bennett EP, Wandall HH et al. 2014. High-efficiency

875

genome editing via 2A-coupled co-expression of fluorescent proteins

876

and zinc finger nucleases or CRISPR/Cas9 nickase pairs. Nucleic Acids

877

Res 42: e84.

878

Elliott B, Richardson C, Winderbaum J, Nickoloff JA, Jasin M. 1998. Gene

879

conversion tracts from double-strand break repair in mammalian cells.

880

Mol Cell Biol 18: 93-101.

881

Faruqi AF, Datta HJ, Carroll D, Seidman MM, Glazer PM. 2000. Triple-helix

882

formation induces recombination in mammalian cells via a nucleotide

883

excision repair-dependent pathway. Mol Cell Biol 20: 990-1000.

884

Ferrara L, Kmiec EB. 2004. Camptothecin enhances the frequency of

885

oligonucleotide-directed gene repair in mammalian cells by inducing

886

DNA damage and activating homologous recombination. Nucleic Acids

887

Res 32: 5239-5248.

888

Garneau JE, Dupuis ME, Villion M, Romero DA, Barrangou R, Boyaval P, 33

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

889

Fremaux C, Horvath P, Magadan AH, Moineau S. 2010. The

890

CRISPR/Cas bacterial immune system cleaves bacteriophage and

891

plasmid DNA. Nature 468: 67-71.

892

Gasiunas G, Barrangou R, Horvath P, Siksnys V. 2012. Cas9-crRNA

893

ribonucleoprotein complex mediates specific DNA cleavage for adaptive

894

immunity in bacteria. Proc Natl Acad Sci U S A 109: E2579-2586.

895

Hastings PJ. 1988. Recombination in the eukaryotic nucleus. Bioessays 9:

896 897 898

61-64. Heyer WD, Ehmsen KT, Liu J. 2010. Regulation of homologous recombination in eukaryotes. Annu Rev Genet 44: 113-139.

899

Huen MS, Li XT, Lu LY, Watt RM, Liu DP, Huang JD. 2006. The involvement of

900

replication in single stranded oligonucleotide-mediated gene repair.

901

Nucleic Acids Res 34: 6183-6194.

902 903

Jasin M, Rothstein R. 2013. Repair of strand breaks by homologous recombination. Cold Spring Harb Perspect Biol 5: a012740.

904

Jensen NM, Dalsgaard T, Jakobsen M, Nielsen RR, Sorensen CB, Bolund L,

905

Jensen TG. 2011. An update on targeted gene repair in mammalian

906

cells: methods and mechanisms. J Biomed Sci 18: 10.

907

Jinek M, Chylinski K, Fonfara I, Hauer M, Doudna JA, Charpentier E. 2012. A

908

programmable dual-RNA-guided DNA endonuclease in adaptive

909

bacterial immunity. Science 337: 816-821.

910 911 912 913

Jinek M, East A, Cheng A, Lin S, Ma E, Doudna J. 2013. RNA-programmed genome editing in human cells. Elife 2: e00471. Kan Y, Ruis B, Lin S, Hendrickson EA. 2014. The mechanism of gene targeting in human somatic cells. PLoS Genet 10: e1004251.

914

Karnan S, Konishi Y, Ota A, Takahashi M, Damdindorj L, Hosokawa Y, Konishi

915

H. 2012. Simple monitoring of gene targeting efficiency in human

916

somatic cell lines using the PIGA gene. PloS one 7: e47389.

917

Katada H, Ren Y, Shigi N, Komiyama M. 2008. Site-specific gene manipulation 34

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

918

of fluorescent proteins using artificial restriction DNA cutter. Nucleic

919

Acids Symp Ser (Oxf) 52: 483-484.

920

Keskin H, Shen Y, Huang F, Patel M, Yang T, Ashley K, Mazin AV, Storici F.

921

2014. Transcript-RNA-templated DNA recombination and repair. Nature

922

515: 436-439.

923 924

Khan IF, Hirata RK, Russell DW. 2011. AAV-mediated gene targeting methods for human cells. Nature Protocols 6: 482-501.

925

Kraus E, Leung WY, Haber JE. 2001. Break-induced replication: a review and

926

an example in budding yeast. Proc Natl Acad Sci U S A 98: 8255-8262.

927

Kuan JY, Glazer PM. 2004. Targeted gene modification using triplex-forming

928

oligonucleotides. Methods Mol Biol 262: 173-194.

929

Langston LD, Symington LS. 2004. Gene targeting in yeast is initiated by two

930

independent strand invasions. Proc Natl Acad Sci U S A 101:

931

15392-15397.

932

Larocque JR, Jasin M. 2010. Mechanisms of recombination between diverged

933

sequences in wild-type and BLM-deficient mouse and human cells. Mol

934

Cell Biol 30: 1887-1897.

935 936

Li J, Baker MD. 2000. Mechanisms involved in targeted gene replacement in mammalian cells. Genetics 156: 809-821.

937

Li J, Read LR, Baker MD. 2001. The mechanism of mammalian gene

938

replacement is consistent with the formation of long regions of

939

heteroduplex DNA associated with two crossing-over events. Mol Cell

940

Biol 21: 501-510.

941

Lin S, Staahl BT, Alla RK, Doudna JA. 2014. Enhanced homology-directed

942

human genome engineering by controlled timing of CRISPR/Cas9

943

delivery. Elife 3: e04766.

944

Liu P, Long L, Xiong K, Yu B, Chang N, Xiong JW, Zhu Z, Liu D. 2014.

945

Heritable/conditional

946

CRISPR-Cas9 feeding system. Cell Res 24: 886-889.

genome

editing

35

in

C.

elegans

using

a

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

947 948

Llorente B, Smith CE, Symington LS. 2008. Break-induced replication: what is it and what is it for? Cell Cycle 7: 859-864.

949

Mao Z, Bozzella M, Seluanov A, Gorbunova V. 2008a. Comparison of

950

nonhomologous end joining and homologous recombination in human

951

cells. DNA Repair (Amst) 7: 1765-1771.

952

Mao Z, Bozzella M, Seluanov A, Gorbunova V. 2008b. DNA repair by

953

nonhomologous end joining and homologous recombination during cell

954

cycle in human cells. Cell Cycle 7: 2902-2906.

955

Murayama Y, Kurokawa Y, Mayanagi K, Iwasaki H. 2008. Formation and

956

branch migration of Holliday junctions mediated by eukaryotic

957

recombinases. Nature 451: 1018-1021.

958

Nishimasu H, Ran FA, Hsu PD, Konermann S, Shehata SI, Dohmae N, Ishitani

959

R, Zhang F, Nureki O. 2014. Crystal structure of Cas9 in complex with

960

guide RNA and target DNA. Cell 156: 935-949.

961

Orr-Weaver TL, Szostak JW. 1983. Yeast recombination: the association

962

between double-strand gap repair and crossing-over. Proc Natl Acad

963

Sci U S A 80: 4417-4421.

964

Orr-Weaver TL, Szostak JW, Rothstein RJ. 1981. Yeast transformation: a

965

model system for the study of recombination. Proc Natl Acad Sci U S A

966

78: 6354-6358.

967

Orthwein A, Noordermeer SM, Wilson MD, Landry S, Enchev RI, Sherker A,

968

Munro M, Pinder J, Salsman J, Dellaire G et al. 2015. A mechanism for

969

the suppression of homologous recombination in G1 cells. Nature 528:

970

422-426.

971

Radecke F, Peter I, Radecke S, Gellhaus K, Schwarz K, Cathomen T. 2006a.

972

Targeted

973

single-stranded oligodeoxynucleotides in the presence of a DNA

974

double-strand break. Mol Ther 14: 798-808.

975

chromosomal

gene

modification

in

human

cells

by

Radecke S, Radecke F, Peter I, Schwarz K. 2006b. Physical incorporation of a 36

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

976

single-stranded oligodeoxynucleotide during targeted repair of a human

977

chromosomal locus. J Gene Med 8: 217-228.

978

Ramirez CL, Certo MT, Mussolino C, Goodwin MJ, Cradick TJ, McCaffrey AP,

979

Cathomen T, Scharenberg AM, Joung JK. 2012. Engineered zinc finger

980

nickases induce homology-directed repair with reduced mutagenic

981

effects. Nucleic Acids Res 40: 5560-5568.

982

Ran FA, Hsu PD, Lin CY, Gootenberg JS, Konermann S, Trevino AE, Scott DA,

983

Inoue A, Matoba S, Zhang Y et al. 2013a. Double nicking by

984

RNA-guided CRISPR Cas9 for enhanced genome editing specificity.

985

Cell 154: 1380-1389.

986

Ran FA, Hsu PD, Wright J, Agarwala V, Scott DA, Zhang F. 2013b. Genome

987

engineering using the CRISPR-Cas9 system. Nat Protoc 8: 2281-2308.

988

Reardon S. 2016. Welcome to the CRISPR zoo. Nature 531: 160-163.

989

Richardson CD, Ray GJ, DeWitt MA, Curie GL, Corn JE. 2016. Enhancing

990

homology-directed genome editing by catalytically active and inactive

991

CRISPR-Cas9 using asymmetric donor DNA. Nat Biotechnol 34:

992

339-344.

993 994

San Filippo J, Sung P, Klein H. 2008. Mechanism of eukaryotic homologous recombination. Ann Rev Biochem 77: 229-257.

995

Shen B, Zhang W, Zhang J, Zhou J, Wang J, Chen L, Wang L, Hodgkins A,

996

Iyer V, Huang X et al. 2014. Efficient genome modification by

997

CRISPR-Cas9 nickase with minimal off-target effects. Nature Methods

998

11: 399-402.

999

Siehler SY, Schrauder M, Gerischer U, Cantor S, Marra G, Wiesmuller L. 2009.

1000

Human

1001

independently of mismatch repair. DNA Repair (Amst) 8: 242-252.

1002

Storici F, Snipe JR, Chan GK, Gordenin DA, Resnick MA. 2006. Conservative

1003

repair of a chromosomal double-strand break by single-strand DNA

1004

through two steps of annealing. Mol Cell Biol 26: 7645-7657.

MutL-complexes

monitor

37

homologous

recombination

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1005

Strathern JN, Klar AJ, Hicks JB, Abraham JA, Ivy JM, Nasmyth KA, McGill C.

1006

1982. Homothallic switching of yeast mating type cassettes is initiated

1007

by a double-stranded cut in the MAT locus. Cell 31: 183-192.

1008 1009 1010 1011 1012 1013 1014 1015

Suzuki T. 2008. Targeted gene modification by oligonucleotides and small DNA fragments in eukaryotes. Front Biosci 13: 737-744. Swuec P, Costa A. 2014. Molecular mechanism of double Holliday junction dissolution. Cell Biosci 4: e36. Symington LS, Gautier J. 2011. Double-strand break end resection and repair pathway choice. Annu Rev Genet 45: 247-271. Wolt JD, Wang K, Yang B. 2016. The regulatory status of genome-edited crops. Plant Biotech J 14: 510-518.

1016

Wright AV, Nunez JK, Doudna JA. 2016. Biology and applications of CRISPR

1017

systems: harnessing nature's toolbox for genome engineering. Cell 164:

1018

29-44.

1019 1020

Wu L, Hickson ID. 2003. The Bloom's syndrome helicase suppresses crossing over during homologous recombination. Nature 426: 870-874.

1021

Wu XS, Xin L, Yin WX, Shang XY, Lu L, Watt RM, Cheah KS, Huang JD, Liu

1022

DP, Liang CC. 2005. Increased efficiency of oligonucleotide-mediated

1023

gene repair through slowing replication fork progression. Proc Natl Acad

1024

Sci U S A 102: 2508-2513.

1025

Yang H, Wang H, Jaenisch R. 2014. Generating genetically modified mice

1026

using CRISPR/Cas-mediated genome engineering. Nat Protoc 9:

1027

1956-1968.

1028

38

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1029

Figure Legends

1030

Figure 1.

1031

antisense cell line. (A) Schematics of the EGFP to BFP conversion system in

1032

the HPRT1-EGFP antisense cell line. An EGFP expression cassette was

1033

knocked into the HPRT1 locus of the HCT116 cell line (only the antisense

1034

orientation is diagrammed here for the sake of ease of presentation).

1035

Genomic lesions could then be introduced near the chromophore (TY residues)

1036

of the EGFP sequence using CRISPR/Cas9 cleavase, nickases or dual

1037

nickases.

1038

the sequence of the SH residues leads to the conversion of EGFP to BFP.

1039

The ODN donors also contained synonymous SNPs that could be

1040

co-converted with the sequence of the SH residues. Schematic elements:

1041

EGFP, green boxes; BFP, blue boxes; HPRT1, inverted yellow boxes;

1042

sequences of the chromophore residues, TY and SH; the cytomegalovirus

1043

promoter, CMV; the polyadenylation sequence, pA; Cas9 variants, red ovals

1044

with scissors; genomic lesions, lightning bolts; ODN donors, horizontal red

1045

lines; synonymous SNPs, vertical blue hashmarks.

1046

conversion in the HPRT1-EGFP antisense cell line.

1047

D10A variant are labeled as Cas9 and nCas9, respectively.

1048

strandedness (S, sense; AS, antisense) of the sgRNA and ODNs (for this

1049

experiment without synonymous SNPs) are labeled with respect to the coding

1050

sequence of EGFP.

1051

complementary to that of the sgRNA. All data are shown as the mean ± SEM

1052

of three biological replicates.

1053

images of each bar shown in (B).

The EGFP to BFP conversion system in the HPRT1-EGFP

HDR repair of the genomic lesions using ODN donors containing

(B) The efficiency of BFP The wildtype Cas9 and The

Note that the Cas9 D10A variant nicks the strand

(C) Single representative flow cytometry

1054 1055

Figure 2. Conversion tracts of single-nick and DSB-induced HDR using ODN

1056

donors.

(A-E) The conversion tracts of single-nick-induced HDR using ODN

39

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1057

donors complementary to (A, B) or the same strand of (C, D) the nick, and

1058

DSB-induced HDR (E).

1059

the retention frequency of each SNP in both 6SNP_A and 6SNP_B donors.

1060

The positions of the SNPs and predicted genomic lesions are labeled in

1061

reference to the center of the chromophore sequence. Schematic elements

1062

are colored as follows: genomic DNA, black; genomic lesions, orange; ODNs,

1063

red; chromophore sequences, TY and SH; SNPs on the 6SNP_A ODNs, blue;

1064

SNPs on the 6SNP_B ODNs, green; homology regions, dashed silver crosses;

1065

strandedness of DNA, S and AS.

1066

synonymous SNPs.

1067

the tri-nucleotides in the S orientation, and the distance between the SNPs and

1068

the center of the SH sequence (TCTCAT) is labeled. Because the last T in

1069

the SH sequence is a wobble nucleotide it could be used as SNP as well and is

1070

represented as the ATG at position +3. ODNs with six distributed or clustered

1071

SNPs are labeled as 6SNP_A (a) and 6SNP_B (b), respectively.

1072

sequences shown at the bottom of the panel emphasize that the S nick is

1073

made at position -1 and the AS nick at position -2.

1074

the ODNs can be found in Supplemental Fig. S8.

The conversion tracts were compiled by overlaying

(F) Schematics of the ODN donors with

The SNPs are represented as the central nucleotide of

The

The actual sequences of

1075 1076

Figure 3.

1077

Repair of complementary strand nicks via SDSA. (B) Repair of nicks on the

1078

same strand via ssDI. Schematic elements are labeled as follows: Top —

1079

genomic DNA, black; genomic lesions and DNA ends, hatched orange lines;

1080

ODNs, red; knock-in mutations, green; resection nucleases, yellow PAC

1081

ManTM; base pairing, purple vertical lines; DNA synthesis, red dashed arrows;

1082

processing nucleases, yellow lightning bolts; Bottom — predicted SNP

1083

retention curves, red dashed line; predicted position of genomic lesions,

1084

orange vertical dashed line; position of the knock-in mutation selected for,

1085

green vertical solid line; regions with more than 50% co-conversion frequency,

Mechanisms of single-nick-induced PGE using ODN donors.

40

(A)

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1086

black double-headed arrows, strandedness of DNA, S and AS; orientations of

1087

the DNA ends, 5’ and 3’.

1088 1089

Figure 4. The conversion tracts of paired-nicks-induced HDR.

1090

conversion tracts of paired-nicks-induced HDR using S (A, B) and AS ODNs (C,

1091

D).

1092

frequency of each SNP in both 6SNP_A and 6SNP_B donors (Fig. 2F).

1093

positions of the SNPs and predicted genomic lesions are labeled in reference

1094

to the center of the chromophore sequence.

1095

colored as in the legend of Fig. 2.

(A-D) The

The conversion tracts were compiled by overlaying the retention The

All schematic elements are

1096 1097

Figure 5.

1098

Repair of the PAM-out double nicks via SDSA.

1099

double nicks via ssDI. All schematic elements are colored and defined as in

1100

the legend to Fig. 3.

Mechanisms of paired-nick-induced PGE using the S ODNs.

(A)

(B) Repair of the PAM-in

1101 1102

Figure 6. The biotin pull-down assay. (A, B) Schematic illustration of the

1103

biotin pull-down assay via the SDSA (A) and ssDI (B) pathways. In the case

1104

of ssDI (B) the biotinylated ODN is predicted to be incorporated into the target

1105

genomic locus whereas in SDSA (A) it should not.

1106

digested genomic fragments covalently linked to biotin can be enriched using

1107

streptavidin beads under denaturing conditions.

1108

BFP_QR can specifically amplify these genomic fragments with ODN

1109

incorporation but not free ODN donors.

1110

orange ovals; genomic DNA, black lines; ODN sequence, solid red lines; DNA

1111

synthesis, dashed red lines; chromophore sequence, TY and SH; genomic

1112

lesions, hatched yellow lines; homology regions, dashed silver crosses;

1113

restriction sites, XhoI and XbaI; PCR primers, horizontal arrows.

1114

of the biotin pull-down assay.

The XhoI and XbaI

The primers BFP_QF and

Biotin, yellow circle; streptavidin,

(C) Results

After transfecting with biotinylated ODNs 41

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

1115

(BFP_S90_Biotin; Supplemental Fig. S8), the BFP-positive cells were

1116

enriched using FACS sorting.

1117

was digested with XhoI and XbaI.

1118

were pulled down with streptavidin beads in denaturing conditions, PCR

1119

amplified using one internal primer and one flanking primer of the ODN donors

1120

(BFP_QF and BFP_QR; Supplemental Fig. S8) and detected on an agarose

1121

gel.

The genomic DNA of the BFP-positive cells The fragments covalently linked to biotin

1122 1123

Figure 7.

1124

PGE is defined as the fraction of HDR leading to the conversion of the desired

1125

knock-in mutations using exogenous homology donors.

1126

retrospectively, the hierarchy of the HDR pathway is determined primarily by

1127

the types of homology donors and secondarily by the genomic lesions.

1128

dsDNA donors containing a sizable central heterology must be converted via

1129

the DSBR model, which generates long conversion tracts with a linear

1130

distribution.

1131

depending on the strandedness of the ODNs and the relative position of the

1132

knock-in mutation to the genomic lesion.

1133

conversion tracts in normal distributions.

1134

presence of double-stranded genomic lesions when both pathways can

1135

convert the knock-in mutation effectively.

The hierarchy of meganuclease-induced HDR leading to PGE.

In the PGE products,

ODN donors can utilize both SDSA and ssDI pathways,

42

These pathways generate short

SDSA is preferentially utilized in the

CMV

HP

B

HP

TY CY EGFP EGFP CY TY

pA

RT

HP

RT

CMV

HP

TY CY pA EGFP RT EGFP CY TY Sense nickase nCas9

RT

nCas9 Antisense nickase Sense oligonucleotides CMV (synonymous SNPs) SH

HP

RT

HP

3

Single nick DSB Paired nicks

2

1

TY CY EGFP pA RT EGFP CY TY 0 (synonymous SNPs) SH Antisense oligonucleotides Cas9: nCas9 nCas9 nCas9 nCas9 Cas9 Cas9 nCas9 nCas9 nCas9 nCas9 CMV sgRNA*: S SH AS S AS S AS PAM- PAM- PAM- PAMCY out in out in pA BFP RT EGFP CY ODNs: S S AS AS AS AS S S AS AS SH *nCas9 (D10A) nicks com plem entary to the strand of the sgRNA Conversion tracts

HP

HP

BFP conversion efficiency (%)

A

RT

A

BS

SH

S

TY

S AS

TY

AS

SH

AS

TCTCAT

100

TCTCAT

ATG

CGC

80 TCA CAC

-60

-40

-20

0

20

40

60

Distance to the central heterology (bp)

C

80

-80

-60

D

-40

-20

CGC

80 TCC

60 TCA

-80

E

-60

-40

-20

100

40

TCA

-80

TCTCAT

100

-60

ATG

80 TCA 60 CAC TCC AAC AAT

-60

0

20

40

SH

(21 bp) GTC

TCTCAT(G) (0 bp) (3 bp)

TCC

GTT GTC CTG AAC CTG

0

20

40

60

Distance to the central heterology (bp)

80

60

6SNP_A (-19 bp) CAC

AAC (42 bp)

6SNP_B

TCC

40 20

-20

-20

(-31 bp) (-7 bp) (9 bp) (30 bp)

(-2 bp)

-40

-40

Distance to the central heterology (bp)

AAC (-40 bp)

DSB 6SNP_A 6SNP_B

GTC CTG AAC CTG

(-2 bp)

F

S AS

-80

AAT

(-61 bp) AAT

CGC

GTT

20

AAC

80

80

TCC

40

TCC

SH

S

60

CAC

60

60

Nick 6SNP_A 6SNP_B

80

CTG

20

ATG

CGC

AAC

0

40

TY

Nick 6SNP_A 6SNP_B

Distance to the central heterology (bp)

20

TCTCAT

GTC CTG

CAC 20 TCC AAT AAC (-1 bp)

CTG

SH

GTT

40

0

S S AS

ATG

AAC

Distance to the central heterology (bp)

TCTCAT

100

CTG

AAT AACTCC CAC (-2 bp)

SH

AS

GTC

TCA 20

TY

S AS

GTT

40

TCC

Nick 6SNP_A 6SNP_B

TCC

60

GTT CTGAAC CTG (-1 bp) GTC

AAT

ATG

80

20

AAC

-80

60 40

TCC

100

CGC

Nick 6SNP_A 6SNP_B

CGC

SH

TCA (-13 bp)

TCC CTG GTT (15 bp)

sgRNA_S: TC//TCAT sgRNA_AS: T//CTCAT

(-1 bp) (-2 bp)

(63 bp) CTG

80

A

Synthesis-Dependent Strand Annealing

S AS

B

Single-Strand DNA Incorporation

S AS

Futile homology search

Minimal 3’ processing S AS

S

5’

3’

3’

5’

S AS

S

Single-strand DNA Incorporation

Strand invasion and synthesis S AS

S

3’

5’ 3’

5’

S AS

S

Strand annealing

Strand displacement

S AS

S

S AS

S

Flap cleavage and ligation

Flap cleavage and ligation S AS

S AS (1) Predicted SNP retention

20 bp (3’)

(2) Predicted SNP retention

10 bp (5’)

20 bp (3’)

10 bp (5’)

A

B

SH

S

TY

S AS CAC

S AS

ATG

80 CAC

6SNP_A 6SNP_B

TCC

AAC

GTT (-1 bp) GTC CTG AAC CTG

(-41 bp)

-60

-40

-20

0

20

40

60

Distance to the central heterology (bp)

C

AAT

80

-80

AAC

TCC

40

-60

(-41 bp)

-40

-20

(-1 bp)

0

0

20

40

60

80

SH

TCTCAT ATG TCC CGC 80

6SNP_A

TCA

6SNP_B

GTT

20 AAT

-20

TY

Paired nicks (PAM-out)

80

TCC 60

-40

Distance to the central heterology (bp)

AS

CGC TCTCAT ATG TCA CAC

(-30 bp)

S AS

SH

AS

-60

GTC CTG AAC CTG (4 bp)

20

D

TY

S AS

GTT 6SNP_B

40

20

AAT

Paired nicks (PAM-in) 6SNP_A

60

TCC

40

-80

TCTCAT CGC ATG TCC TCA

Paired nicks (PAM-out)

60

-80

TY

CGC TCTCAT

TCA TCC 80

AAC

SH

S

60

40

60

CTG

Distance to the central heterology (bp)

80

AAT

-80

-60

GTC CTG

20 CAC TCC AAC (-30 bp)

-40

-20

6SNP_A 6SNP_B

40

GTC CTG AAC

20

GTT

Paired nicks (PAM-in)

0

AAC (4 bp)

20

CTG

40

60

Distance to the central heterology (bp)

80

A

Synthesis-Dependent Strand Annealing Paired nicking (PAM-out)

S AS 3’

S AS

5’

Single-Strand DNA Incorporation Paired nicking (PAM-in)

S AS

Extensive 5’ resection

Futile homology search

5’

S

3’

3’

5’

S AS

S 3’

S AS

B

Strand invasion, 3’ processing and synthesis

Single-strand DNA incorporation

5’

S

5’

3’ 3’

5’

S AS

S Strand annealing

Strand displacement

S AS

S

S Flap cleavage, ligation and single-strand gap repair

S AS

S AS

Flap cleavage, ligation and single-strand nick repair

S AS (3) Predicted conversion tracts

(4) Predicted conversion tracts

A

B

Biotin SH

XhoI

XbaI

TY

XhoI

XhoI

XbaI

BFP_CF

C

ssDI

XhoI

SH SH

SH

XbaI

TY

SDSA

Digest Pull-down Denature

Biotin SH

XbaI

SH SH

Digest Pull-down Denature

Strepavidin

BFP_CF

BFP_QR

SH

Cas9

nCas9

nCas9

Cas9

nCas9

nCas9

sgRNA*

S

AS

AS

PAM-out

PAM-in

ODNs

S

S

S

S

S

Model

SDSA

ssDI

SDSA

SDSA

ssDI

Input (25 cycles) Output (40 cycles) *nCas9 (D10A) nicks com plem entary to the strand of the sgRNA

Strepavidin BFP_QR

Meganuclease-induced precise genome engineering

dsDNA donors (for large mutations)

ODN donors (for small modifications)

including viruses with dsDNA intermediates

Homology

Heterology

DSBs Double-strand break repair (0) Conversion tracts

Homology Effective complementary Effective same strand lesion strand lesion

Nicks Inefficient

Synthesis-dependent strand annealing (1) Conversion tracts

-20 bp Effective conversion zone(~kb)

Single-strand DNA Incorporation (2) Conversion tracts

+10 bp

Effective conversion zone (~30 bp)

-20 bp

+10 bp

Effective conversion zone (~30 bp)

Downloaded from genome.cshlp.org on April 20, 2017 - Published by Cold Spring Harbor Laboratory Press

Mechanisms of precise genome editing using oligonucleotide donors Yinan Kan, Brian Ruis, Taylor Takasugi, et al. Genome Res. published online March 29, 2017 Access the most recent version at doi:10.1101/gr.214775.116

P