ARTICLE

Received 10 Sep 2014 | Accepted 24 Apr 2015 | Published 11 Jun 2015

The primary dynamics in photomachinery such as charge separation in photosynthesis and bond isomerization in sensory photoreceptor are typically ultrafast to accelerate functional dynamics and avoid energy dissipation. The same is also true for the DNA repair enzyme, photolyase. However, it is not known how the photoinduced step is optimized in photolyase to attain maximum efciency. Here, we analyse the primary reaction steps of repair of ultraviolet-damaged DNA by photolyase using femtosecond spectroscopy. With systematic mutations of the amino acids involved in binding of the avin cofactor and the cyclobutane pyrimidine dimer substrate, we report our direct deconvolution of the catalytic dynamics with three electron-transfer and two bond-breaking elementary steps and thus the ne tuning of the biological repair function for optimal efciency. We found that the maximum repair efciency is not enhanced by the ultrafast photoinduced process but achieved by the synergistic optimization of all steps in the complex repair reaction.

DOI: 10.1038/ncomms8302

The molecular origin of high DNA-repair efciency by photolyase

Chuang Tan1,*, Zheyun Liu1,*, Jiang Li1, Xunmin Guo1, Lijuan Wang1, Aziz Sancar2 & Dongping Zhong1

1 Department of Physics, Department of Chemistry and Biochemistry, and Programs of Biophysics, Chemical Physics, and Biochemistry, The Ohio State University, Columbus, Ohio 43210, USA. 2 Department of Biochemistry and Biophysics, University of North Carolina School of Medicine, Chapel Hill, North Carolina 27599, USA. * These authors contributed equally to this work. Correspondence and requests for materials should be addressed to D.Z. (email: mailto:[email protected]

Web End [email protected] ).

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Photochemical machines in nature are powered by sunlight to execute important biological functions such as photo-synthesis for light energy conversion to chemical energy

and photosensory function for signal transduction16. To reach high biological efciency, the initial photoinduced dynamics are usually ultrafast to quickly funnel excitation energy into the functional coordinate(s) and avoid futile energy dissipation into the environment24. In addition to photosynthesis and photosignalling, blue light energy is used as a co-substrate for repairing DNA damage by photolyase with high quantum yield7,8. The photoenzyme performs biotransformation with multiple elementary chemical steps9,10, and at present it is not known whether the initial ultrafast photoinduced process is the determinant of high efciency. Thus, a key question in photolyase research is how the enzyme optimizes elementary chemical reactions to achieve the high efciency and the role of the rate of the initial photoinduced process in achieving high quantum yield.

We recently mapped out the entire dynamics of DNA repair with six elementary reactions using femtosecond spectroscopy to follow the complete functional evolution (Fig. 1a)1114. We observed two consecutive competitions of these elementary steps that make key contributions to the nal repair efciency: the rst one is the forward electron transfer (ET, tFET) from the excited

cofactor avin (FADH *) to substrate thymine dimer (To4T), the major UV-induced DNA photoproduct15, against the deactivation process (tLT), leading to the rst-branching

quantum yield FFET of 0.85. The second is the ultrafast splitting of the C5-C50 and the C6-C60 bonds (tSP2) relative to the futile back electron transfer (tBET) without repair, resulting in the second-branching quantum yield FSP2 0.96 (Fig. 1a). The

overall repair efciency (FT) is the product of the two quantum yields and thus is as high as 0.82.

To understand how the enzyme achieves this high quantum efciency, we use an oligonucleotide substrate containing cyclobutane thymine dimer (To4T) and examine the contributions of the amino acids involved in the binding of cofactor (FADH ) and substrate (cyclobutane pyrimidine dimer in DNA)

to catalysis by using mutant enzymes that affect cofactor and substrate interactions as well as activate site dynamics that tune each elementary step in this multi-step catalytic reaction. We reveal that the maximal repair efciency results from the overall synergy of all elementary steps.

ResultsOligonucleotide substrate and critical active-site mutants. Previously, we investigated functional dynamics of photolyase by using di-pyrimidine cyclobutane dimers of various compositions and ultrafast spectroscopy and found that the enzyme repairs cyclobutane dimers with high quantum yield. To gain further insight into the contributions of various factors in the active site to catalytic efciency in this study we used an oligonucleotide

F

o

r

w

a

r

d

E

T

2

5

0

p

s

N386 (N378)

FADH *

3.2

O R R

O

HN

NH

C

5

O

O

R R

O

N

N

O

n

C

- 5

FADH

o

HN

5

3

ti

a

<

s

p

1 li

0 tt

i

n

g

6

6

v

E283

O

N N

NH

5 5

5

3.7

3.0

O

M353 (M345)

R350 (R342)

c

ti

FADH

p

s

a

(E274)

e

3

D

m

Photolyase

n

s

2.9

3.5

h

0

n

0

3

O

O

5

1

.

R

R

-

0

T<>T

HN

NH

2.8

2.4

0

3

3.2

R232

O

N

N

O

3.1

(R226)

5

3

3

3.5

FADH

T<>T

5

FADH

O O

2

.

4

n

s

R R

0.8

QY

O

O

HN

NH

WT 0.820.72

M345A0.67

N378C0.62

N378S0.53

R226A0.48

R342A0.38

F

u

ti

l

e

b

a

c

k

E

T

R

R

HN

NH

O

N N

O

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3

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5

O

7

0

0

p

s

5

3

E

l

e

c

t

r

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r

e

t

u

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Absorption

0.4

s

9

0

p

6

s

p

li

tt

i

n

g

E274A

C

6

-

C

0.0

0

100 200

Irradiation time (min)

Figure 1 | Repair photocycle of ultraviolet-damaged DNA by E.coli photolyase and the key functional residues in the active site with corresponding repair quantum yields. (a) The repair photocycle of UV-damaged DNA (thymine dimer) by photolyase with six elementary steps including one deactivation, three electron transfer and two bond-breaking reactions. Two competing processes with four main steps reduce the overall repair quantum efciency. (b) Local structure at the active site with ve critical residues (green), the cofactor avin (orange) and substrate thymine dimer (cyan). The mutants of each of the ve residues were examined for their contributions to the modulation of repair efciency. Note the active site enzymesubstrate contacts are based on A. nidulans photolyase-substrate co-crystal structure. The numbers in parenthesis indicate the corresponding residues in E. coli photolyase. (c) Repair kinetics and repair quantum yields (QY) of wild-type photolyase and the six mutants analysed in this study.

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1.0

0.5

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0 800 1,600 2,400

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N378S M345A

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[afii9838] =300 nm

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Normalized A

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[afii9838] =800 nm [afii9838] =620 nm

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[afii9838] =270 nm

[afii9838] =266 nm

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1.00.5

0.5 1.0

0.0

0.5

Flavins T-TT

0 800 1,600 2,400

0 600 1,200 1,800 2,400

Time delay (ps)

Figure 2 | Transient-absorption signals of three mutants probed by a wide range of wavelengths from visible to UV region at 400 nm excitation. (a) Absorption transients probed at 800 nm for detection of the excited-state avin (FADH*) and at 620 nm mainly for the intermediate-state avin (FADH ). Shown in the inset is the deconvolution of the FADH* and FADH contributions. The latter is from two channels (dashed lines). (bd) Absorption transients probed at (b) 300 nm, (c) 270 nm and (d) 266 nm with distinct dynamic patterns for each mutant. Shown in the insets is the deconvolution of the transient signals with detection of initial reactants, subsequent intermediates and nal products for (b) M345A, (c) N378S and (d) R226A.

substrate and mutant forms of the enzyme that affect either the redox properties of the avin or the properties of the substrate with following considerations. At the binding pocket of the substrate, salt bridges and hydrogen bonds are formed between the To4T dimer and amino-acid residues: protonated E274 could form two hydrogen bonds with N3 and O4 of the 50-thy-mine; R226 has both electrostatic interaction and hydrogen bond with 50-thymine; R342 interacts with 30-thymine not only through salt bridge but also through the water network. These hydrophilic interactions could disperse the excessive electron density and help stabilize the generated radical anion of the dimer after electron injection from FADH *. Thus, the mutations of these binding-site residues would reduce the stabilization and lead to the decrease in the reduction potential of To4T/ To4T .

As these mutations do not affect the reduction potential of the avin cofactor, the free energy DG0FET (DG0FET jFADH

=FADH-

jTo4T=To4T

- 2:48eV) becomes less negative than that of

the wild type. On the avin cofactor side, N378 is opposite to the N5 position of avin, and its side carbonyl group forms a hydrogen bond with the N(5)H group of FADH or FADH .

Destroying the interaction would abolish the ability of photolyase to stabilize the FADH radical16. These ve critical residues at the active site that were studied are shown in Fig. 1b: N378 near the cofactor forms a hydrogen bond with the N5 atom of avin, M345 is in the middle between the avin cofactor and 30 base of the substrate, and E274, R226 and R342 are around the substrate with the former two residues having hydrogen bonding with the 50 base and the latter one forming a hydrogen-bond network with water molecules and the 30 base17,18. We found that N378 mutated to serine (S) or cysteine (C) was necessary to obtain stable proteins, for the other four residues we used an alanine (A) scanning mutagenesis. Figure 1c shows our measurement of the total repair quantum yields of these six mutants, which ranges from 0.38 to 0.72, with the wild type (WT) having the highest repair efciency of 0.82.

Ultrafast electron injection and electron return. To understand how each mutation modulates the elementary steps in catalysis, we mapped out the entire repair dynamics for each mutant from the initial reactants to subsequent intermediates and to nal products, and thus resolved each elementary reaction and determined their reaction timescales. Figure 2 shows ve typical transient-absorption signals detected by a series of wavelengths from visible to UV light region for three mutants of M345A, N378S and R226A. At 800 nm, only the excited FADH * dynamics is detected. All the dynamics in the presence of substrate follow a stretched single-exponential decay (Fig. 2a and Supplementary Fig. 1a), Ae t=t

b

(A, amplitude; t, decay time constant; and b, stretched parameter), due to the modulation of ET by active-site solvation on similar timescales1113,19,20. Using t

h i t=bG1=b and knowing the deactivation lifetimes (tLT)

in nanoseconds in the absence of substrate (Supplementary Fig. 2 and Supplementary Table 1), we derived the average forward ET times (tFET) for six mutants (Fig. 3a and Supplementary Table 1)

and observed a signicant change from 236 ps for the WT to 140 ps for M345A and 1,181 ps for N378C, reecting the strong modulation of initial photoinduced processes by the active-site critical residues. These measurements are accurate and the experiments were repeated for more than four times. Given by our single-to-noise ratio, the time constants we obtained here and thereafter have an error of o10%. From these lifetimes, we obtained the rst-branching quantum yields (FFET) shown in

Fig. 3a (Supplementary Table 1). Knowing the total repair yields (Figs 1c and 3a), we obtained the second-branching quantum yields (FSP2) as also shown in Fig. 3a. At 620 nm, all the transient signals become slower because we also detected the intermediate radical FADH in addition to the excited FADH * (Fig. 2a and

Supplementary Fig. 1a). After subtracting the excited-state FADH * signals, we obtained the overall formation and decay dynamics of the intermediate FADH (inset in Fig. 2a and

Supplementary Fig. 1a). The formation dynamics reects the

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Reaction times (ps) Reaction yields [afii9838] (eV)

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N378S R226A

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1 ns

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G 0 (eV)

Figure 3 | The derived reaction times, various quantum yields and electron-transfer reorganization energies involved in DNA repair by photolyase. (a) The reaction times for ve elementary reactions involved in repair. LT deactivation lifetime; FET forward electron transfer;

BET back electron transfer; SP2 the second C6-C60 splitting;

ER electron return after repair. The rst C5-C50 splitting is ultrafast for all

mutants within 10 ps and not shown here. The dashed lines link two sets of two competition channels responsible for the repair efciency. Also shown are the corresponding quantum yields of FFET and FSP2 for the two sets of

competitions and the resulting total quantum yield of FT (FFET FSP2).

(b) Two-dimensional (2D) contour plot of the electron-transfer dynamics relative to free energy (DG0) and reorganization energy (l) for FET (lled circle), BET (open square) and ER (open diamond) obtained in this study.

The former two are in the ET normal region and the latter one is in the Marcus inverted region.

initial ET process of the excited FADH * and the decay dynamics represents the electron return to the cofactor and the completion of the entire photocycle.

Dimer splitting and repair photocycle. To reveal the complete photocycle and determine how the dimer splits, we tuned our probing wavelengths to the UV region to detect thymine-related species. Figures 2bd show three typical transients probed at 300, 270 and 266 nm with the markedly different dynamic patterns, reecting the different contributions of various species. Knowing the avin dynamics above and the second-branching quantum yields FSP2 from FT/FFET (Fig. 3a), with a global analysis of all transients based on the resolved repair model (Fig. 1a, see Supplementary Note 1 for detailed analyses)13, we resolved the dynamics of T-T after ultrafast C5-C50 bond breaking (Fig. 2c,d), T formation after complete dimer splitting (Fig. 2b) and T formation after electron return to restore the active cofactor (Figs 2bd), and thus determined the sequential

dynamics of the dimer splitting, the dynamics of futile back ET (tBET) without repair and the electron return (tER) after successful repair (Figs 1a and 3a), also revealing the total intermediate FADH decay (inset in Fig. 2a) from the two contributions of the branched back ET and repair channels (dashed lines).

Reaction timescales and repair efciency. All the dynamics and timescales of the elementary reactions are shown in Fig. 3a (Supplementary Table 1). To reach high repair efciency FT, both the rst-branching FFET and second-branching FSP2 need to be as large as possible, that is, the FET and dimer splitting should be as fast as possible, and the deactivation process and futile BET as slow as possible. Clearly, mutations either at the cofactor side or the substrate side signicantly modulate the three ET reactions of FET, BET and ER. For the dimer splitting, the rst C5-C50 bond breakage is ultrafast in o10 ps13,21,22 for all the mutants but the critical second C6-C60 cleavage is modulated by the mutations around the substrate. Specically, for M345A, the FET (140 ps) is faster than that of the WT (236 ps), leading to an even larger FFET of 0.89. All other mutants have slower FET dynamics, resulting in a smaller FFET of 0.740.62 than the WT (0.85). For the competition between the dimer splitting and futile BET, all the mutants have faster futile BET dynamics. Although the mutants of R226A and E274A have faster C6-C60 splitting dynamics, their BET also becomes faster. Finally, all mutations result in a smaller FSP2 of 0.930.62. For M345A, although the initial photoinduced reaction is even faster than the WT with the largest FFET, the smaller FSP2 dominates and therefore leads to a lower FT. Thus, unlike other biological photochemical systems, the initial photoinduced process in photolyase does not have to be ultrafast and the main determinant of overall high repair efciency. For all other ve mutants, both the smaller FFET and

FSP2 lead to a lower total repair efciency FT of 0.670.38 (Fig. 3a).

DiscussionThe signicant modulation of the three ET reactions by the mutations provides insight to contributing factors to overall repair efciency. The deactivation process and the second C6-C60 bond splitting, except for N378C and E274A, respectively, are quite similar (Fig. 3a). Thus, the interplay between FET and BET is critical to modulating the repair yield. The WT enzyme has the slowest BET (2.4 ns) and very faster FET (236 ps), leading to the highest repair yield. For all the mutants, the FET dynamics with the exception of M345A become slower and all the BET processes become faster, and thus unfavourable for repair. To understand these changes, we evaluated these ET reactions using the Marcus ET theory to estimate the driving forces ( DG0) and

reorganization energies (l)2326 for each form of the enzyme (see Supplementary Note 2). Figure 3c shows the derived results of DG0 and l for the FET, BET and ER. The FET is in the Marcus normal region ( DG0rl). The BET is a dissociative ET

process21. For the C5-C50 cleavage, the BET has a small driving force and is in the normal region again, due to a high energy of the neutral intermediate T-T after charge recombination21,25. The ER after repair is in the Marcus inverted region ( DG0Zl). The

mutations considerably alter not only the free energy changes, that is, the reduction potentials of the cofactor or the substrate, but also the reorganization energies20,25,26 and thus signicantly modulate all three ET reactions. The derived large reorganization energies mainly come from the contributions of the different structural distortions of FADH and FADH (refs 25,27). The obtained changes of driving forces and reorganization energies for three ET reactions by mutations are basically correlated with the local structural and chemical properties (for details, see

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WT

M345A

N378C

N378S

R226A

R342A

E274A

Dynamic tuning by active-site mutations

FET

LT

ER

SP2

BET

100 100 1,000Reaction dynamics (ps)

100 1,000

1,000

FADH*

T <>T

T T

T+T

C6-C6 splitting

FET

Free energy

C5-C5 splitting

Intact BET

Ring reclosure

LT

BET

ER

T<>T

T+T

Reaction coordinate

Figure 4 | Reaction free-energy prole along reaction coordinate for complex enzymatic DNA repair. Six elementary reaction steps (solid lines) with the structures of the excited cofactor avin (orange) and all thymine-related intermediates (blue) and products (green). The relative energy between each state is mainly determined from our dynamic measurements. The seventh elementary step of intact BET (dashed line) is slow and does not happenin the entire repair due to the ultrafast C5-C50 splitting. The reactions times are displayed at the top to show direct modulation of ve elementary steps by the six mutations with the wild type included for comparison.

Supplementary Note 3: inuence of the mutations on the electron transfer reactions and the dimer splitting).

Figure 4 shows the entire energy prole of the enzymatic repair along the reaction coordinate with at least six fundamental steps including the excited-state deactivation, three ET elementary reactions and two sequential bond breaking and making processes. To maximize the repair efciency, the enzyme has a relatively rigid active site, structurally and electrostatically, to avoid the ultrafast deactivation from the buttery bending motion and lengthen the excited-state lifetime27,28, and a favourable redox environment to lead to an appropriate FET, not too slow so as to result in lower FFET and not too fast so as to cause faster

BET with a lower FSP2. After charge separation, the reaction proceeds to the ultrafast C5-C50 bond splitting, thus eliminating the rst intact charge-recombination channel to the original ground state without the dimer splitting. After the rst C5-C50 bond breaking, the reaction encounters a small barrier for the second C6-C60 bond splitting and the reaction bifurcates. The second charge-recombination channel that leads to the closure of the dimer ring again competes with the productive second C6-C60 bond cleavage, leading to a loss of the repair yield. The redox property at the active site is synergistically optimized to balance the FET and BET processes relative to the excited-state deactivation and the dimer splitting, respectively, to achieve the maximum outcome. After the complete dimer splitting, the third charge-recombination channel, the elector return to restore the active avin cofactor and complete the repair photocycle, should not be too slow to avoid new damage of repaired DNA by the extra electron29. Any mutation as studied here that modulates the active-site reduction potentials and ET reorganization energies always breaks the dedicated synergy of the optimization for the main four elementary reactions in two competitions, and thus leads to lower repair efciency than the WT enzyme.

Methods

Preparation of photolyase and mutants. The purication of E. coli photolyase without the antenna cofactor has been reported elsewhere30,31. For mutant enzyme studies, we mutated a series of key residues at the active site (R226A, E274A, N341A, R342A, M345A, N378C and N378S) using QuikChange II XL kit (Stratagene) based on the plasmid of wild-type enzyme. All mutated plasmids were sequenced to conrm the mutations and ensure the absence of secondary mutations. After the standard purication, all mutant proteins were obtained with stoichiometric avin except N341A that lacks the FAD cofactor. In femtosecond spectroscopic studies, 100 mM of enzyme (or 50 mM in experiments with probe wavelengths of shorter than 300 nm) was used in a reaction buffer containing 100 mM NaCl, 50 mM Tris-HCl at pH 7.5, 20 mM dithiothreitol, 1 mM EDTA and 50% (v/v) glycerol.

Preparation of cyclobutane thymine dimer substrate. We prepared the cyclobutane thymine dimer (To4T) substrate from oligo(dT)15 as described elsewhere with some modication32. In brief, we dissolved 3 mg oligo(dT)15 (synthesized by Integrated DNA Technologies) in 1 ml 15% aqueous acetone (v/v). The argon-purged DNA solutions were irradiated over ice with a 302-nm UVB lamp (General Electric) at a 2-cm distance for 5070 min. To4T formation was monitored by decreases in absorbance at 260 nm. In the nal products, there are about ve To4T dimers in each strand of oligo(dT)15. The concentration of the oligosubstrates used in the femtosecond studies is 3 mM (or 1.5 mM in experiments with probe wavelengths of shorter than 300 nm).

Enzyme activities. The enzyme activities of the wild-type and mutant photolyases were quantitatively measured. Procedures for determination of dissociation constants and relative quantum yields of the mutants were described before13,25. For each mutant, a set of mixtures of 1 mM enzyme with different concentrations (111, 333, 500 and 1,000 mM) of To4T-containing oligo(dT)15 substrate was prepared. These samples in cuvettes were irradiated at the room temperature using white-light lamp (General Electric) at the same distance of 6 cm. The absorption spectra of each mixture were recorded at a series of illumination times. The increased absorbance around 266 nm is a measure of the formation of thymine bases.

Figure 1c shows typical steadystate repair measurements for the wild-type and six mutant photolyases. For each enzymesubstrate binding complex (ES), the absorbance change at 266 nm was plotted vs illumination times, and the slope is directly proportional to the binding complex concentration ([ES]) and the repair

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efciency of the enzyme. Considering that some part of enzymes is not bound with substrates, the dissociation constants (Kd) for each mutant need to be carefully determined. The binding complex percentage ([ES]/[E]) for each enzyme is plotted against different substrate concentrations (Supplementary Fig. 3),and the dissociation constants were t by the equation [ES]/[E] [S]/([S] Kd).

The derived dissociation constants are 8.3 10 6, 1.2 10 5, 1.4 10 5,

2.0 10 4, 5.0 10 5, 2.4 10 5 and 1.2 10 5 M for wild type (WT), E274A,

R226A, R342A, M345A, N378C and N378S, respectively. R342A has the largest dissociation constant, which is consistent with the crystal structure that R342 has many H-bonds with the water network at the binding site and the direct interaction with the phosphate of DNA backbone18.

The repair quantum yields for the mutants were calculated by comparing the slopes of mutants with that of WT (Fig. 1c), taking account of the enzyme substrate concentration extracted from the dissociation constants. Knowing the repair quantum yield of the WT to be 0.82 (refs 8,13,25,33), the repair quantum yields for the mutants were obtained (Supplementary Table 1).

Femtosecond-resolved spectroscopy. All the femtosecond-resolved measurements were carried out using transient absorption methods. The laser experimental layout and procedure have been detailed elsewhere34,35. One-mm quartz cuvettes (Starna) were used as the sample cell in experiments with the probe wavelengths of shorter than 300 nm, while 5-mm cuvettes were used for other experiments. The samples were stirred during irradiation to avoid heating and photobleaching. All experiments in the femtosecond-resolved measurements were carried out under anaerobic conditions.

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Acknowledgements

We thank Dr Ya-Ting Kao for help with the experiments. This work was supported in part by the National Institute of Health Grant GM074813 (D.Z.) and GM31082 (A.S.).

Author contributions

D.Z. designed the research. C.T., Z.L., J.L., X.G. and L.W. performed the research. C.T., Z.L. and D.Z. analysed the data. C.T., Z.L., A.S. and D.Z. wrote the paper. All authors discussed and edited the manuscript.

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How to cite this article: Tan, C. et al. The molecular origin of high DNA-repair efciency by photolyase. Nat. Commun. 6:7302 doi: 10.1038/ncomms8302 (2015).

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