DNA duplex recognition activates Exo1 nuclease activity

Exonuclease 1 (Exo1) is an evolutionarily conserved eukaryotic nuclease that plays a multifaceted role in maintaining genome stability. The biochemical attributes of Exo1 have been extensively characterized via conventional assays. However, the key step governing its activation remains elusive. Extending the previous finding that Exo1 can digest a randomly selected single-stranded DNA (ssDNA) but not a poly(dT) oligonucleotide and using purified recombinant Exo1 and nuclease and electrophoretic mobility shift assays, here we determined that DNA hairpins with a stem size of 4 bp or longer are able to activate Exo1-mediated digestion of ssDNA. We further provide evidence suggesting that Exo1 uses an evolutionarily conserved residue, Lys185. This residue interacted with the phosphate group bridging the third and fourth nucleotide on the digestion strand of the substrate DNA for duplex recognition, critical for Exo1 activation on not only ssDNA but also dsDNA. Additionally, the defect of an exo1-K185A mutant in duplex digestion was partially rescued by longer overhanging DNA. However, we noted that the enhanced Exo1 nuclease activity by longer overhanging DNA is largely eliminated by replication protein A (RPA), likely because of the previously reported RPA activity that strips Exo1 off the ssDNA. We conclude that duplex DNA contact by Exo1 is a general mechanism that controls its activation and that this mechanism is particularly important for digestion of duplex DNA whose nascent ssDNA is bound by RPA.

Exonuclease 1 (Exo1) is an evolutionarily conserved eukaryotic nuclease that plays a multifaceted role in maintaining genome stability. The biochemical attributes of Exo1 have been extensively characterized via conventional assays. However, the key step governing its activation remains elusive. Extending the previous finding that Exo1 can digest a randomly selected single-stranded DNA (ssDNA) but not a poly(dT) oligonucleotide and using purified recombinant Exo1 and nuclease and electrophoretic mobility shift assays, here we determined that DNA hairpins with a stem size of 4 bp or longer are able to activate Exo1-mediated digestion of ssDNA. We further provide evidence suggesting that Exo1 uses an evolutionarily conserved residue, Lys 185 . This residue interacted with the phosphate group bridging the third and fourth nucleotide on the digestion strand of the substrate DNA for duplex recognition, critical for Exo1 activation on not only ssDNA but also dsDNA. Additionally, the defect of an exo1-K185A mutant in duplex digestion was partially rescued by longer overhanging DNA. However, we noted that the enhanced Exo1 nuclease activity by longer overhanging DNA is largely eliminated by replication protein A (RPA), likely because of the previously reported RPA activity that strips Exo1 off the ssDNA. We conclude that duplex DNA contact by Exo1 is a general mechanism that controls its activation and that this mechanism is particularly important for digestion of duplex DNA whose nascent ssDNA is bound by RPA.
Exo1 is an evolutionarily conserved Rad2 family nuclease that plays a multifaceted role in DNA metabolic pathways governing genome stability, including mismatch repair (1)(2)(3), homologous recombination (HR) 2 -mediated double-strand break (DSB) repair (4), telomere maintenance, lagging strand maturation, and recovery of stalled replication forks (5,6). Exo1 was first isolated from fission yeast, Schizosaccharomyces pombe, undergoing meiosis and revealed to degrade dsDNA from its 5Ј end, leaving a 3Ј single-stranded DNA (ssDNA) tail (7). Later, Exo1 was also found to carry 5Ј flap endonuclease activity. The functions of Exo1 are largely fulfilled via its 5Ј-to-3Ј dsDNA exonuclease activity, which is capable of digesting a 5Ј end embedded in a double-strand break or a gapped or nicked duplex. In mismatch repair, Exo1 removes long tracts of DNA, including the mispaired nucleotide (2,8). The reaction presumably starts from a nick in a manner directed by MutS/L family mismatch repair proteins (2,3,8,9). In both telomere maturation and HR-mediated DSB repair, the 3Ј ssDNA overhang generated by Exo1 from a chromosomal end or a DSB end allows assembly of either the telomeric nucleoprotein complex or the Rad51 nucleoprotein filament. At stalled replication forks, Exo1 digests the nascent laggingstrand DNA to suppress fork reversal and prevent replication fork collapse (5,6,10). A major function derived from Exo1's 5Ј flap endonuclease activity is in lagging-strand maturation, where overexpressing Exo1 suppresses the temperature-sensitive phenotype of rad27⌬ in budding yeast (1).
As a key repair enzyme, Exo1 is both positively and negatively regulated by protein factors and posttranslational modifications. MutS␣ in mismatch repair, MRX(N) and 9-1-1 complexes in DSB end resection have been reported to enhance the processivity of Exo1/hEXO1 (3,(11)(12)(13). On the other hand, the DNA damage checkpoint down-regulates Exo1, which imposes a negative feedback loop on DNA end resection (14) and stabilizes a stalled replication fork from Exo1 digestion (6,15). In addition, the Ku complex, a key player in the nonhomologous end joining pathway, which competes with HR in DSB repair, strongly inhibits Exo1-catalyzed digestion of a DSB end (16 -18). It remains puzzling that the Ku complex protects DSB ends from Exo1 digestion but allows their access by the ligase IV complex to join the broken chromosome (19,20).
The crystal structure of the human EXO1 (hEXO1) catalytic core  in complex with its substrate DNA has been solved, which elucidated the molecular details of the Exo1 nuclease reaction. Based on the crystal structures, hEXO1 has been proposed to accommodate substrates subjected to both exonucleolytic and endonucleolytic digestion with a well-superimposed conformation, catalyzing both reactions with the same catalytic center (21). Interestingly, binding of hEXO1 to the duplex region of its substrate DNA was captured as the first snapshot in a further time-resolved crystallography study (22), which suggests duplex capture as a critical step in Exo1/hEXO1 activation. However, this premise remains to be tested in functional assays.
Besides duplex and 5Ј flap DNA, Exo1 is also able to degrade ssDNA (11). ssDNA digestion by Exo1, a reaction strongly inhibited by RPA (11), is less well characterized and is intriguing because a poly(dT) oligonucleotide is completely resistant to Exo1-digestion (23). The drastic difference between a regular oligonucleotide and a poly(dT) as substrate for Exo1, however, provides a unique system to define the mechanism of Exo1 activation. Here, with this system, we determined that Exo1 is highly versatile in capturing transient hairpin structures with a stem size of 4 bp or longer, which, in turn, activates Exo1 to digest ssDNA via a combination of endonucleolytic and exonucleolytic mechanisms. The available hEXO1 crystal structures led us to further identify a highly conserved lysine 185 from hEXO1/Exo1, which interacts with the phosphate group bridging the third and fourth nucleotide on the digestion strand of the substrate DNA. Importantly, the corresponding lysine-toalanine mutation of Lys 185 not only disrupted ssDNA digestion by Exo1 but also largely impaired Exo1-catalyzed digestion of a duplex DNA and failed to fully complement the CPT sensitivity of exo1⌬ in yeast. Thus, duplex contact by Exo1 is a general mechanism to control Exo1 activation.

ssDNA digestion by Exo1 is sequence selective
Exo1 has been reported to digest regular ssDNA substrates (11) but not a poly(dT) oligonucleotide (23), which provides a biochemical system to determine the key factor(s) in Exo1 activation. Recombinant budding yeast Exo1 with a WT coding sequence is poorly expressed in Escherichia coli; hence, current biochemical studies employ either insect cells or yeast as the host system to express and purify recombinant Exo1 (4, 24 -27). By codon-optimizing Exo1's primary coding sequence, we managed to express and purify the full-length Exo1 and a nuclease-dead mutant, exo1-D173A, from E. coli (Fig. S1A). Consistent with previous studies (11,23), purified Exo1 is able to digest an 80-mer oligonucleotide (H80) randomly selected from our laboratory stock but not a (dT) 80 oligonucleotide (Fig.  1A).Moreover,poly(dA),poly(dT),poly(dC),andpoly(dG)oligonucleotides were all refractory to Exo1 digestion (Fig. S1B). Thus, ssDNA digestion by Exo1 is not simply due to its preference to cleave at a certain nucleotide.

Hairpin formation drives Exo1-catalyzed digestion of ssDNA
A titration of Exo1 on 3Ј end-labeled H80 revealed intermediates that gradually decreased in size (Fig. 1A) and clustered between 7 and 22 nt from the 5Ј end of H80. With an increasing amount of Exo1, the digestion reached as far as ϳ 7 nt toward the 3Ј end. Sequence analysis of the H80 oligonucleotide revealed two relative stable hairpins, each with a stem region of 5 bp in length (Fig. 1B). One hairpin is located at the very 3Ј end of H80. The other hairpin, with a stem size of 5 bp plus a G-A mismatch within the stem, is located between 8 and 23 nt from the 5Ј end (Fig. 1B), a position where the digestion intermediates proximal to the 5Ј end were clustered. Importantly, deletion of 40 bases from the 3Ј end of H80 or replacing them with thymidine nucleotides, which remove the 3Ј hairpin and result in H40 and H40 -40T oligonucleotides, respectively, limited the bulk of digestion to a position prior to the end of 5Ј hairpin (Fig. 1A). Thus, in Exo1-catalyzed ssDNA degradation, an embedded hairpin is important to trigger Exo1 digestion of its 5Ј upstream DNA.

Exo1 digests ssDNA via a combination of exonucleolytic and endonucleolytic mechanisms
When the digestion of 3Ј end-labeled H80 by Exo1 was examined closely, the step size of intermediates showed a mixture of both endo-and exonucleolytic cleavage events (Fig. 1A). To confirm this, H80, H40 -40T, and H40 were 5Ј end-labeled and tested for their initial cleavage by Exo1. For H80 and H40 -40T, both exonucleolytic and endonucleolytic products were detected, with the major endonucleolytic cleavage sites located in the 5Ј hairpin loop of H80 and H40 -40T (Fig. 1C). Interestingly, unlike H40 -40T, deletion of the 3Ј hairpin in H40 not only decreased the overall reaction rate but also caused a nearly 3-fold reduction in endonucleolytic product formation (Fig. 1C). Notably, the only difference between H40 -40T and H40 is the length of 3Ј ssDNA adjoining the 5Ј hairpin, where a longer 3Ј ssDNA in H40 -40T stimulates hairpin-activated ssDNA cleavage by Exo1.

Hairpin formation promotes binding of Exo1 to ssDNA substrates
human EXO1 is a threading enzyme for endonucleolytic digestion, where a 5Ј flap needs to thread through the binding pocket for its cleavage (22). Binding of streptavidin to a 3Ј-biotinylated (dT) 40 oligonucleotide, which presumably traps Exo1 on ssDNA, did not activate its digestion by Exo1 (Fig. S1C). Therefore, the hairpinactivated Exo1 cleavage of ssDNA is not simply due to hairpinmediated pausing of Exo1 during its ssDNA threading. Alternatively, we surmise that a transient duplex region donated by the embedded hairpin may facilitate Exo1 loading. Therefore, EMSAs were conducted with exo1-D173A, a nuclease-dead version of Exo1, to avoid substrate digestion. Under physiological salt conditions (150 mM KCl), tight binding of exo1-D173A to ssDNA was observed, with a low nanomolar apparent K d (Fig. 1D). Importantly, exo1-D173A displayed a nearly 2-fold higher affinity for the hairpin-forming H80 over (dT) 80 (Fig. 1D). Therefore, the hairpin structures embedded in ssDNA likely facilitate its complex formation with Exo1.

DNA hairpin with a stem size of as short as 4 bp is sufficient to activate Exo1
Hairpins in H80 have a maximum stem size of 5 bp and are likely dynamic but sufficient for Exo1 to capture. To further characterize the transient nature of DNA hairpins utilized by Exo1, ssDNA substrates with more defined hairpins were constructed, where three, four, or six adenine nucleotide runs were engineered proximal to the 3Ј end of a (dT) 35 oligonucleotide to allow formation of hairpin DNA but with the potential of various loop sizes ( Fig. 2A). As a control, a fixed hairpin DNA (3Ј-6GC) based on six G-C pairs was also designed ( Fig. 2A). Consistent with an early report where the presence of a hairpin strongly interrupts heteroduplex formation (28), minimal interstrand pairing was observed when the 5Ј end-labeled oligonucleotides were analyzed by native PAGE (Fig. S2A). Upon their incubation with Exo1, little reaction was observed with 3Ј-3A (Fig. 2B). Digestion occurred on 3Ј-4A and 3Ј-6A, with both exonucleolytic and endonucleolytic products detected. The 3Ј-6A substrate is around 2-fold more reactive than the 3Ј-4A substrate (Fig. 2B). Notably, on the 3Ј-6GC substrate with a fixed hairpin, exonucleolytic digestion is considerably Activation of Exo1 nuclease on single-stranded DNA less compared with 3Ј-4A and 3Ј-6A (Fig. 2B). We surmise that the 5Ј Ts in 3Ј-4A and 3Ј-6A may pair with the As at the 3Ј end to promote exonucleolytic digestion, which would not occur in 3Ј-6GC. To summarize, the results suggest that a hairpin with a stem size of 4 bp or longer in ssDNA is able to trigger its cleavage by Exo1. To find the endpoint of Exo1 digestion on hairpincontaining ssDNA, we installed a series of adenine nucleotide runs 3 nt away from the 5Ј end of a (dT) 35 oligonucleotide, which allows potential hairpin formation proximal to the 5Ј end of ssDNA (Fig. S2B). Again, minimal digestion occurred on the 5Ј-3A substrate. With the 5Ј-4A substrate, the major products observed are single and dinucleotide removal (Fig. S2B). Increasing the insertion length to six As drives the cleavage to 5-6 nt from the 5Ј end, with three or four As retained (Fig.  S2B). Further increasing the insertion length to eight As extends the cleavage to 6 -7 nt from the 5Ј end, with four or five As retained (Fig. S2B). These results, again, confirm the minimal requirement of a 4-bp stem length to activate Exo1. Second, hairpin-activated ssDNA digestion by Exo1 is limited prior to the 3Ј end of the hairpin structure.

Hairpin-mediated cleavage is an attribute of the Exo1 nuclease core
Exo1 has a highly conserved nuclease core at its N terminus and a less conserved C-terminal tail. To determine whether hairpin-mediated ssDNA digestion requires the C terminus of Exo1, we first mapped the core domain of yeast Exo1, which retains its full nuclease activity. The crystallized nuclease core domain of hEXO1 contains its N-terminal 352 amino acids and is fully active in vitro (21). The yeast exo1(1-348), which spans the nuclease core region conserved between yeast and human, is, however, nearly 10-fold less active regarding its exonuclease activity against a 5Ј-recessed DNA end bearing a 7-nt ssDNA overhang (Fig. S3A). Extension of the C terminus to amino acid 403 fully restored its nuclease activity (Fig. S3A), which thus represents a minimal catalytic core of Exo1. Importantly, the ability of exo1(1-403) to digest ssDNA resembles that of the full-length Exo1 (Fig. S3B). We conclude that hairpin-mediated ssDNA digestion is an attribute of the Exo1 nuclease core domain.

Regulation of Exo1 catalyzed digestion of ssDNA by RPA
Exo1 is a threading enzyme (21). Binding of RPA to ssDNA may impose a barrier for threading, inhibiting ssDNA digestion by Exo1 (11,29). Similarly, as reported, digestion of 3Ј endlabeled H80 by Exo1 is inhibited by RPA but not RPA-A Ϫ B Ϫ , an RPA mutant defective in DNA binding (Fig. 3A). Importantly, in a similar reaction but with 5Ј end-labeled H80, RPA inhibits not only endonucleolytic digestion but also exonucleolytic

Activation of Exo1 nuclease on single-stranded DNA
cleavage (Fig. 3B). We speculate that binding of RPA to ssDNA also removes DNA hairpins, blocking Exo1.

The exo1-K185A mutation confers a defect in nuclease activation and causes CPT sensitivity in cells
Our study of hairpin-directed ssDNA digestion by Exo1 showed that a duplex region with a minimum length of 4 bp is necessary to support Exo1 digestion. In the crystal structure of hEXO1 bound to its substrate duplex DNA with a recessed 5Ј end (22), a highly conserved lysine 185 (Fig. 4A) forms a salt bridge/hydrogen bond with the phosphate group that connects the third and fourth base from the 5Ј end of the digestion strand; therefore, it may be critical in duplex recognition. Mutation of lysine 185 into alanine (Fig. S1A) resulted in nearly complete inactivation of Exo1 on degrading 3Ј-4A and 3Ј-6A substrates (Fig. 4B). Importantly, compared with WT Exo1, the exo1-K185A mutant also displayed a 3-to 4-fold reduction in its exonuclease activity against a recessed 5Ј end with a 7-nt ssDNA overhang (Fig. 4C). Extension of the overhanging length to 27 nt did not affect the exonuclease activity of WT Exo1, regardless of the absence or presence of RPA (Fig. S4A). Changing the overhang length from 7 nt to 27 nt, on the other hand, increased the exonuclease activity of the exo1-K185A mutant by nearly 2-fold, which was, however, largely offset by the presence of RPA (Fig. S4B). Collectively, our results suggest that duplex recognition is critical to trigger Exo1 activation, which is particularly important when the ssDNA region of 3Ј-overhanging DNA is either short or RPA bound (Fig. 5). To ascertain the importance of duplex recognition for the function of Exo1 in cells, we sought to find out whether the exo1-K185A mutation renders yeast cells sensitive to DNAdamaging agents. exo1⌬ is only mildly sensitive to DNAdamaging agents and has been reported to cause slow growth of yeast cells in the presence of camptothecin (CPT) (14,30), a chemotherapeutic drug that traps the topoisomerase 1 cleavage complex on DNA and blocks DNA replication (31). Ectopic expression of WT EXO1 but not exo1-K185A from a CEN plasmid complemented the CPT sensitivity of the exo1⌬ strain (Fig. 4D). Thus, duplex recognition is important for Exo1 function in cells.

Discussion
Exo1, a multitasking nuclease in eukaryotes, has been characterized extensively as a 5Ј-3Ј dsDNA exonuclease and 5Ј flap endonuclease (32,33). Exo1 prefers dsDNA bearing a 3Ј ssDNA overhang (11) The 3Ј adjoining ssDNA, which enhances the exonuclease activity of Exo1, is, however, not essential for Exo1 activation, as Exo1 is still capable of digesting a blunt-ended duplex DNA, albeit less actively (11,16,34). Here we reported that a duplex region as short as 4 bp provided by a hairpin is sufficient to trigger Exo1-catalyzed digestion of an ssDNA sub-

Activation of Exo1 nuclease on single-stranded DNA
strate. Guided by the available crystal structure of hEXO1, we further isolated a point mutation, K185A, that disrupts the interaction between Lys 185 and the phosphate group bridging the third and fourth nucleotide at the 5Ј end of the digestion strand. The purified exo1-K185A mutant protein not only failed to digest hairpin DNA but also showed defects in exonucleolytic digestion of a duplex DNA. Moreover, the K185A mutation also renders yeast cells sensitive to the DNA-damaging agent camptothecin. These results confirm the necessity of duplex recognition in Exo1 activation (Fig. 5) and are in congruence with the time-resolved X-ray crystallography study of hEXO1, where binding of hEXO1 to the duplex region of a 3Ј overhang DNA substrate was captured as the first available snapshot (22).
Notably, the initial substrate engagement by EXO1 involves an annotated contact between Exo1 and the sixth nucleotide on the nondigestion strand (21,22). Indeed, compared with 3Ј-4A, Exo1 is 2-fold more active on the 3Ј-6A substrate, where the stem size of the embedded hairpin was increased from 4 to 6 bp. Therefore, we surmise that Exo1 may recognize the DNA duplex via a bimodal interface, where Lys 185 plays an important role in its nuclease activation.
Biochemically, Exo1 displayed increased exonuclease activity when the 3Ј overhanging length was increased from 4 nt to ϳ100 nt (11). Interestingly, we also observed overhanging length-dependent enhancement of Exo1 activity on both single-strand and duplex DNA. Compared with H40 in ssDNA digestion, H40 -40T extends the length of the 3Ј hairpin-adjoining ssDNA from 17 nt to 57 nt, which not only enhances the cleavage efficiency of Exo1 but also results in a considerable increase in endonucleolytic product formation. In duplex digestion, extending the 3Ј overhang length from 7 nt to 27 nt partially compensated for the defect of exo1-K185A in vitro. We therefore surmise that the 3Ј-adjoining ssDNA may facilitate initial Exo1 loading and its activation in a duplex-dependent manner (Fig. 5). However, enhancement of Exo1 nuclease activity by longer overhanging DNA is largely eliminated by the presence of RPA. This is likely due to the reported activity of RPA in stripping Exo1 off the ssDNA (12). Knowing that longer ssDNA tails are likely RPA-bound in cells, the duplex recognition mechanism by Exo1 is likely critical in digesting duplex DNA, where the nascent ssDNA is readily occupied by RPA.
Among factors that regulate Exo1, the Ku complex, a key component of the nonhomologous end joining machinery, strongly inhibits Exo1-catalyzed digestion from a DSB end but allows ligase IV-catalyzed end joining, regulating the pathway choice of DSB repair. Knowing that the Ku complex, a ringshaped heterodimer, binds to the end of duplex DNA and shields approximately the last two helical turns (35), our finding that duplex binding is critical for the action of Exo1 suggests a mechanism utilized by the Ku complex to specifically inhibit Exo1/hEXO1 at a DSB end. The knowledge acquired in this work will also shed light on the regulation of Exo1 resection by other means, such as its down-regulation by the DNA damage checkpoint in yeast (6,14,15).

Expression and purification of Exo1 from E. coli
The coding sequence of Exo1 (1-348) was redesigned through codon optimization by Genscript (sequence available upon request) to facilitate its expression in E. coli. The synthesized gene with an engineered C-terminal His 6 tag was cloned into pET21a to yield pET21a-exo1(1-348). To construct expression vectors for the full-length Exo1 and exo1(1-403), the coding sequences of various Exo1 C-terminal fragments were amplified from genomic DNA (S288C) and fused in-frame with the synthesized coding sequence of exo1(1-348) using an internal BamHI restriction site starting at 627 nt, resulting in pET21a-Exo1 and pET21a-exo1(1-403), respectively. To express full-length Exo1 in E. coli, pET21a-Exo1 was transformed into Rosetta TM (DE3)pLys cells (Novagen). Overnight culture of E. coli cells harboring pET21a-Exo1 was diluted into 12 liters of Luria-Bertani medium with a dilution factor of 1:50. When the A 600 of the culture reached 0.6 -0.8, isopropyl 1-thio-␤-D-galactopyranoside was added to the culture to a final concentration of 0.5 mM. The cell culture was further incubated overnight at 16°C to induce Exo1 expression. A cell pellet  Activation of Exo1 nuclease on single-stranded DNA of ϳ 30 g was harvested from 12 liters of cell culture and stored at Ϫ80°C for future use.

DNA substrates
The sequence of non-poly(dT)-derived oligonucleotides used in this work is listed in Table S1. For 5Ј end labeling, the oligonucleotide was incubated with T4 polynucleotide kinase (New England Biolabs) in the presence of [␥-32 P]ATP (PerkinElmer Life Sciences) at 37°C for 1 h. For 3Ј end labeling, the oligonucleotide was incubated with terminal deoxynucleotidyltransferase (New England Biolabs) in the presence of [␣-32 P]cordycepin 5Ј-triphosphate at 37°C for 1 h. After the labeling reaction, the remaining free mononucleotides were removed by passing the sample through a Micro Bio-Spin TM 6 column (Bio-Rad). Duplex DNA substrates were constructed by annealing the respective oligonucleotides in 1ϫ NEBuffer 3 (50 mM Tris-HCl (pH 7.9), 10 mM MgCl 2 , 100 mM NaCl, and 1 mM DTT) using a PCR machine programmed as follows: 95°C for 5 min, followed by a 0.2°C decrease per minute to 25°C. Specifically, D1 or D1-27 was annealed with D2 to create a duplex DNA with a 7-nt or 27-nt 3Ј overhang, respectively.

Nuclease assays
Exo1 nuclease assays were conducted in a 10-l reaction system where 5 nM DNA substrate was incubated with the indicated amount of Exo1 in reaction buffer containing 20 mM Tris-HCl (pH 8.0), 2 mM MgCl 2 , 150 mM KCl, 1 mM DTT, and 200 g/ml BSA at 30°C for 10 min. To stop and deproteinize the reaction, the mixture was further incubated with 0.2% SDS and 0.5 mg/ml proteinase K at 37°C for 5 min before heat treatment at 95°C for 5 min in loading buffer (95% formamide, 0.025% (w/v) bromphenol blue, 0.025% (w/v) orange G, and 5 mM EDTA). The sample was chilled on ice for 5 min and then frac-tionated in 20% polyacrylamide denaturing gel electrophoresis running in 0.5ϫ Tris borate-EDTA buffer before phosphorimaging analysis.

Electrophoretic mobility shift assays
Electrophoretic mobility shift assays of the exo1-D173A nuclease dead mutant were carried out in a 10-l reaction system that contains 40 mM Tris-HCl (pH 8.0), 2 mM MgCl 2 , 150 mM KCl, 1 mM DTT, 200 g/ml BSA, and 5 nM DNA substrate and the indicated amount of exo1-D173A. The samples were incubated at 30°C for 10 min. For each reaction, 2 l of 6ϫ loading dye (10 mM Tris-HCl (pH 8.0), 0.025% (w/v) orange G, and 50% glycerol) was added. The mixture was fractionated on a 6% native polyacrylamide gel running in 0.5ϫ Tris borate-EDTA buffer before phosphorimaging analysis.