Flap endonucleases pass 5'-flaps through a flexible arch using a disorder-thread-order mechanism to confer specificity for free 5'-ends

Flap endonucleases (FENs), essential for DNA replication and repair, recognize and remove RNA or DNA 5'-flaps. Related to FEN specificity for substrates with free 5'-ends, but controversial, is the role of the helical arch observed in varying conformations in substrate-free FEN structures. Conflicting models suggest either 5'-flaps thread through the arch, which when structured can only accommodate single-stranded (ss) DNA, or the arch acts as a clamp. Here we show that free 5'-termini are selected using a disorder-thread-order mechanism. Adding short duplexes to 5'-flaps or 3'-streptavidin does not markedly impair the FEN reaction. In contrast, reactions of 5'-streptavidin substrates are drastically slowed. However, when added to premixed FEN and 5'-biotinylated substrate, streptavidin is not inhibitory and complexes persist after challenge with unlabelled competitor substrate, regardless of flap length or the presence of a short duplex. Cross-linked flap duplexes that cannot thread through the structured arch react at modestly reduced rate, ruling out mechanisms involving resolution of secondary structure. Combined results explain how FEN avoids cutting template DNA between Okazaki fragments and link local FEN folding to catalysis and specificity: the arch is disordered when flaps are threaded to confer specificity for free 5'-ends, with subsequent ordering of the arch to catalyze hydrolysis.     

The structure of Escherichia coli ExoIX—implications for DNA binding and catalysis in flap endonucleases

Escherichia coli Exonuclease IX (ExoIX), encoded by the xni gene, was the first identified member of a novel subfamily of ubiquitous flap endonucleases (FENs), which possess only one of the two catalytic metal-binding sites characteristic of other FENs. We have solved the first structure of one of these enzymes, that of ExoIX itself, at high resolution in DNA-bound and DNA-free forms. In the enzyme–DNA cocrystal, the single catalytic site binds two magnesium ions. The structures also reveal a binding site in the C-terminal domain where a potassium ion is directly coordinated by five main chain carbonyl groups, and we show this site is essential for DNA binding. This site resembles structurally and functionally the potassium sites in the human FEN1 and exonuclease 1 enzymes. Fluorescence anisotropy measurements and the crystal structures of the ExoIX:DNA complexes show that this potassium ion interacts directly with a phosphate diester in the substrate DNA.     

Kinetic and functional analysis of the small RNA methyltransferase HEN1: The catalytic domain is essential for preferential modification of duplex RNA

The HEN1 RNA methyltransferase from Arabidopsis thaliana catalyzes S-adenosyl-L-methionine (AdoMet)-dependent 2′-O-methylation at the 3′-termini of small double-stranded RNAs and is a crucial factor in the biogenesis of plant small noncoding RNAs, such as miRNAs or siRNAs. We performed functional and kinetic studies of the full-length HEN1 methyltransferase and its truncated form comprising the C-terminal part of the protein (residues 666–942) with a variety of model RNA substrates. Kinetic parameters obtained with natural RNA substrates indicate that HEN1 is highly catalytically efficient in the absence of any supplementary proteins. We find that the enzyme modifies individual strands in succession leading to complete methylation of an RNA duplex. The rates of methyl group transfer to individual strands of hemimethylated substrates under single turnover conditions are comparable with the multiple turnover rate under steady-state conditions, suggesting that release of reaction products is not a rate-limiting event in the reaction cycle. The truncated protein, which includes conserved motifs characteristic for AdoMet binding, efficiently modifies double-stranded RNA substrates in vitro; however, in contrast to the full-length methyltransferase, it shows weaker interactions with both substrates and is sensitive to base mispairing in the first and second positions of the RNA duplex. Our findings suggest an important role for the N-terminal domains in stabilizing the catalytic complex and indicate that major structural determinants required for selective recognition and methylation of RNA duplexes reside in the C-terminal domain.     

Experimental and theoretical analysis of the invasive signal amplification reaction

The invasive signal amplification reaction is a sensitive method for single nucleotide polymorphism detection and quantitative determination of viral load and gene expression. The method requires the adjacent binding of upstream and downstream oligonucleotides to a target nucleic acid (either DNA or RNA) to form a specific substrate for the structure-specific 5' nucleases that cleave the downstream oligonucleotide to generate signal. By running the reaction at an elevated temperature, the downstream oligonucleotide cycles on and off the target leading to multiple cleavage events per target molecule without temperature cycling. We have examined the performance of the FEN1 enzymes from Archaeoglobus fulgidus and Methanococcus jannaschii and the DNA polymerase I homologues from Thermus aquaticus and Thermus thermophilus in the invasive signal amplification reaction. We find that the reaction has a distinct temperature optimum which increases with increasing length of the downstream oligonucleotide. Raising the concentration of either the downstream oligonucleotide or the enzyme increases the reaction rate. When the reaction is configured to cycle the upstream instead of the downstream oligonucleotide, only the FEN1 enzymes can support a high level of cleavage. To investigate the origin of the background signal generated during the invasive reaction, the cleavage rates for several nonspecific substrates that arise during the course of a reaction were measured and compared with the rate of the specific reaction. We find that the different 5' nuclease enzymes display a much greater variability in cleavage rates on the nonspecific substrates than on the specific substrate. The experimental data are compared with a theoretical model of the invasive signal amplification reaction.     

Three metal ions participate in the reaction catalyzed by T5 flap endonuclease

Protein nucleases and RNA enzymes depend on divalent metal ions to catalyze the rapid hydrolysis of phosphate diester linkages of nucleic acids during DNA replication, DNA repair, RNA processing, and RNA degradation. These enzymes are widely proposed to catalyze phosphate diester hydrolysis using a "two-metal-ion mechanism." Yet, analyses of flap endonuclease (FEN) family members, which occur in all domains of life and act in DNA replication and repair, exemplify controversies regarding the classical two-metal-ion mechanism for phosphate diester hydrolysis. Whereas substrate-free structures of FENs identify two active site metal ions, their typical separation of > 4 A appears incompatible with this mechanism. To clarify the roles played by FEN metal ions, we report here a detailed evaluation of the magnesium ion response of T5FEN. Kinetic investigations reveal that overall the T5FEN-catalyzed reaction requires at least three magnesium ions, implying that an additional metal ion is bound. The presence of at least two ions bound with differing affinity is required to catalyze phosphate diester hydrolysis. Analysis of the inhibition of reactions by calcium ions is consistent with a requirement for two viable cofactors (Mg2+ or Mn2+). The apparent substrate association constant is maximized by binding two magnesium ions. This may reflect a metal-dependent unpairing of duplex substrate required to position the scissile phosphate in contact with metal ion(s). The combined results suggest that T5FEN primarily uses a two-metal-ion mechanism for chemical catalysis, but that its overall metallobiochemistry is more complex and requires three ions.     

Three-dimensional electron microscopy of the reverse gyrase from Sulfolobus tokodaii

Reverse gyrase is a type IA topoisomerase, found in various hyperthermophiles and promotes ATP-dependent positive supercoiling of DNA. Electron microscopy combined with single particle analyses revealed the three-dimensional structure of the DNA-free Sulfolobus tokodaii reverse gyrase and two-dimensional average images of both the protein alone and that complexed with double-stranded DNA. The 23A resolution map exhibited a parallelogrammatic morphology of 110 x 87 x 43A, which is in good agreement with the crystal structure of the Archaeoglobus fulgidus reverse gyrase. The average image of the complex revealed that the monomeric enzyme binds DNA duplex. Together with this average image of the complex, the three-dimensional map implies that, at the beginning of the supercoiling reaction, DNA is bound within a 10-20A wide cleft in the helicase-like domain. We also speculate that DNA may pass through a 20A wide hole at the end of the cleft.     

Cleavage specificity of Saccharomyces cerevisiae flap endonuclease 1 suggests a double-flap structure as the cellular substrate

Flap endonuclease 1 (FEN1) is a structure-specific nuclease that cleaves substrates containing unannealed 5'-flaps during Okazaki fragment processing. Cleavage removes the flap at or near the point of annealing. The preferred substrate for archaeal FEN1 or the 5'-nuclease domains of bacterial DNA polymerases is a double-flap structure containing a 3'-tail on the upstream primer adjacent to the 5'-flap. We report that FEN1 in Saccharomyces cerevisiae (Rad27p) exhibits a similar specificity. Cleavage was most efficient when the upstream primer contained a 1-nucleotide 3'-tail as compared with the fully annealed upstream primer traditionally tested. The site of cleavage was exclusively at a position one nucleotide into the annealed region, allowing human DNA ligase I to seal all resulting nicks. In contrast, a portion of the products from traditional flap substrates is not ligated. The 3'-OH of the upstream primer is not critical for double-flap recognition, because Rad27p is tolerant of modifications. However, the positioning of the 3'-nucleotide defines the site of cleavage. We have tested substrates having complementary tails that equilibrate to many structures by branch migration. FEN1 only cleaved those containing a 1-nucleotide 3'-tail. Equilibrating substrates containing 12-ribonucleotides at the end of the 5'-flap simulates the situation in vivo. Rad27p cleaves this substrate in the expected 1-nucleotide 3'-tail configuration. Overall, these results suggest that the double-flap substrate is formed and cleaved during eukaryotic DNA replication in vivo.     

Purification and properties of an endonuclease from nuclei of uninfected and polyoma-infected 3T3 cells.

An endonuclease activity has been purified approximately 800-fold from nuclei of 3T3 cells infected with polyoma virus. The purfied enzyme catalyzes an endonucleoytic cleavage of single- and double-stranded DNA and single-stranded RNA. Evidence that the activity towards these substrates resides in the same protein molecule is provided by the finding that they co-sediment in sucrose gradients and have identical rates of heat inactivation. Studies on the DNase activity shows that the rate of hydrolysis of single-stranded T7 DNA is 100-fold greater than that for double-stranded T7 DNA. Single-stranded DNA is extensively hydrolyzed to low molecular weight acid-insoluble products. With duplex DNA as substrate, only a limited number of single strand breaks are introduced. A limit digest with polyoma DNA (component I) as substrate results in the introduction of four breaks per strand. The phosphdiester bond interruptions can be repaired by polynucleotide ligase. Approximately 80% of the 5' termini present at the point of phosphodiester bond cleavage are purine nucleotides. Additional studies have demonstrated that a similar endonuclease is present in nuclei of uninfected cells and that this enzyme purified 400-fold has catalytic properties identical with those of the endonuclease from infected cells.     

Observation of unpaired substrate DNA in the flap endonuclease-1 active site

The structure- and strand-specific phosphodiesterase flap endonuclease-1 (FEN1), the prototypical 5′-nuclease, catalyzes the essential removal of 5′-single-stranded flaps during replication and repair. FEN1 achieves this by selectively catalyzing hydrolysis one nucleotide into the duplex region of substrates, always targeting the 5′-strand. This specificity is proposed to arise by unpairing the 5′-end of duplex to permit the scissile phosphate diester to contact catalytic divalent metal ions. Providing the first direct evidence for this, we detected changes induced by human FEN1 (hFEN1) in the low-energy CD spectra and fluorescence lifetimes of 2-aminopurine in substrates and products that were indicative of unpairing. Divalent metal ions were essential for unpairing. However, although 5′-nuclease superfamily-conserved active-site residues K93 and R100 were required to produce unpaired product, they were not necessary to unpair substrates. Nevertheless, a unique arrangement of protein residues around the unpaired DNA was detected only with wild-type protein, suggesting a cooperative assembly of active-site residues that may be triggered by unpaired DNA. The general principles of FEN1 strand and reaction-site selection, which depend on the ability of juxtaposed divalent metal ions to unpair the end of duplex DNA, may also apply more widely to other structure- and strand-specific nucleases.     

Cleavage of a DNA-RNA-DNA/DNA chimeric substrate containing a single ribonucleotide at the DNA-RNA junction with prokaryotic RNases HII

We have analyzed the cleavage specificities of various prokaryotic Type 2 ribonucleases H (RNases H) on chimeric DNA-RNA-DNA/DNA substrates containing one to four ribonucleotides. RNases HII from Bacillus subtilis and Thermococcus kodakaraensis cleaved all of these substrates to produce a DNA segment with a 5'-monoribonucleotide. Consequently, these enzymes cleaved even the chimeric substrate containing a single ribonucleotide at the DNA-RNA junction (5'-side of the single ribonucleotide). In contrast, Escherichia coli RNase HI and B. subtilis RNase HIII did not cleave the chimeric substrate containing a single ribonucleotide. These results suggest that bacterial and archaeal RNases HII are involved in excision of a single ribonucleotide misincorporated into DNA.     

A comparison of eubacterial and archaeal structure-specific 5'-exonucleases.

The 5'-exonuclease domains of the DNA polymerase I proteins of Eubacteria and the FEN1 proteins of Eukarya and Archaea are members of a family of structure-specific 5'-exonucleases with similar function but limited sequence similarity. Their physiological role is to remove the displaced 5' strands created by DNA polymerase during displacement synthesis, thereby creating a substrate for DNA ligase. In this paper, we define the substrate requirements for the 5'-exonuclease enzymes from Thermus aquaticus, Thermus thermophilus, Archaeoglobus fulgidus, Pyrococcus furiosus, Methanococcus jannaschii, and Methanobacterium thermoautotrophicum. The optimal substrate of these enzymes resembles DNA undergoing strand displacement synthesis and consists of a bifurcated downstream duplex with a directly abutted upstream duplex that overlaps the downstream duplex by one base pair. That single base of overlap causes the enzymes to leave a nick after cleavage and to cleave several orders of magnitude faster than a substrate that lacks overlap. The downstream duplex needs to be 10 base pairs long or greater for most of the enzymes to cut efficiently. The upstream duplex needs to be only 2 or 3 base pairs long for most enzymes, and there appears to be interaction with the last base of the primer strand. Overall, the enzymes display very similar substrate specificities, despite their limited level of sequence similarity.     

Flap Endonuclease 1 Mechanism Analysis Indicates Flap Base Binding Prior to Threading

FEN1 cleaves 5′ flaps at their base to create a nicked product for ligation. FEN1 has been reported to enter the flap from the 5′-end and track to the base. Current binding analyses support a very different mechanism of interaction with the flap substrate. Measurements of FEN1 binding to a flap substrate show that the nuclease binds with similar high affinity to the base of a long flap even when the 5′-end is blocked with biotin/streptavidin. However, FEN1 bound to a blocked flap is more sensitive to sequestration by a competing substrate. These results are consistent with a substrate interaction mechanism in which FEN1 first binds the flap base and then threads the flap through an opening in the protein from the 5′-end to the base for cleavage. Significantly, when the unblocked flap length is reduced from five to two nucleotides, FEN1 can be sequestered from the substrate to a similar extent as a blocked, long flap substrate. Apparently, interactions related to threading occur only when the flap is greater than two to four nucleotides long, implying that short flaps are cleaved without a threading requirement.     

Control of Catalytic Cycle by a Pair of Analogous tRNA Modification Enzymes

Enzymes that use distinct active site structures to perform identical reactions are known as analogous enzymes. The isolation of analogous enzymes suggests the existence of multiple enzyme structural pathways that can catalyze the same chemical reaction. A fundamental question concerning analogous enzymes is whether their distinct active-site structures would confer the same or different kinetic constraints to the chemical reaction, particularly with respect to the control of enzyme turnover. Here, we address this question with the analogous enzymes of bacterial TrmD and its eukaryotic and archaeal counterpart Trm5. TrmD and Trm5 catalyze methyl transfer to synthesize the m1G37 base at the 3′ position adjacent to the tRNA anticodon, using S-adenosyl methionine (AdoMet) as the methyl donor. TrmD features a trefoil-knot active-site structure whereas Trm5 features the Rossmann fold. Pre-steady-state analysis revealed that product synthesis by TrmD proceeds linearly with time, whereas that by Trm5 exhibits a rapid burst followed by a slower and linear increase with time. The burst kinetics of Trm5 suggests that product release is the rate-limiting step of the catalytic cycle, consistent with the observation of higher enzyme affinity to the products of tRNA and AdoMet. In contrast, the lack of burst kinetics of TrmD suggests that its turnover is controlled by a step required for product synthesis. Although TrmD exists as a homodimer, it showed half-of-the-sites reactivity for tRNA binding and product synthesis. The kinetic differences between TrmD and Trm5 are parallel with those between the two classes of aminoacyl-tRNA synthetases, which use distinct active site structures to catalyze tRNA aminoacylation. This parallel suggests that the findings have a fundamental importance for enzymes that catalyze both methyl and aminoacyl transfer to tRNA in the decoding process.     

Crystal structure of the catalytic core of Rad2: insights into the mechanism of substrate binding

Rad2/XPG belongs to the flap nuclease family and is responsible for a key step of the eukaryotic nucleotide excision DNA repair (NER) pathway. To elucidate the mechanism of DNA binding by Rad2/XPG, we solved crystal structures of the catalytic core of Rad2 in complex with a substrate. Rad2 utilizes three structural modules for recognition of the double-stranded portion of DNA substrate, particularly a Rad2-specific α-helix for binding the cleaved strand. The protein does not specifically recognize the single-stranded portion of the nucleic acid. Our data suggest that in contrast to related enzymes (FEN1 and EXO1), the Rad2 active site may be more accessible, which would create an exit route for substrates without a free 5′ end.     

Unzipping mechanism of the double-stranded DNA unwinding by a hexameric helicase: the effect of the 3' arm and the stability of the dsDNA on the unwinding activity of the Escherichia coli DnaB helicase

The effect of two structural elements of a replication DNA fork substrate, the length of the 3' arm of the fork and the stability of the double-stranded DNA (dsDNA) part, on the kinetics of the dsDNA unwinding by the Escherichia coli hexameric helicase DnaB protein has been examined under single turnover conditions using the rapid quench-flow technique. The length of the 3' arm of the replication fork, i.e. the number of nucleotides in the arm, is a major structural factor that controls the unwinding rate and processivity of the helicase. The data show the existence of an optimal length of the 3' arm where there is the highest unwinding rate and processivity, indicating that during the unwinding process, the helicase transiently interacts with the 3' arm at a specific distance on the arm with respect to the duplex part of the DNA. Moreover, the area on the enzyme that engages in interactions has also a discrete size. For DNA substrates with the 3' arm containing 14, or less, nucleotide residues, the DnaB helicase becomes a completely distributive enzyme. However, the 3' arm is not a "specific activating cofactor" in the unwinding reaction. Rather, the 3' arm plays a role as a mechanical fulcrum for the enzyme, necessary to provide support for the advancing large helicase molecule on the opposite strand of the DNA. Binding of ATP is necessary to engage the 3' arm with the DnaB helicase, but it does not change the initial distribution of complexes of the enzyme with the DNA fork substrate. Stability of the dsDNA has a significant effect on the unwinding rate and processivity. The unwinding rate constant is a decreasing linear function of the fractional content of GC base-pairs in the dsDNA, indicating that the activation of the unwinding step is proportional to the stability of the nucleic acid.     

Neutralizing mutations of carboxylates that bind metal 2 in T5 flap endonuclease result in an enzyme that still requires two metal ions

Flap endonucleases (FENs) are divalent metal ion-dependent phosphodiesterases. Metallonucleases are often assigned a "two-metal ion mechanism" where both metals contact the scissile phosphate diester. The spacing of the two metal ions observed in T5FEN structures appears to preclude this mechanism. However, the overall reaction catalyzed by wild type (WT) T5FEN requires three Mg(2+) ions, implying that a third ion is needed during catalysis, and so a two-metal ion mechanism remains possible. To investigate the positions of the ions required for chemistry, a mutant T5FEN was studied where metal 2 (M2) ligands are altered to eliminate this binding site. In contrast to WT T5FEN, the overall reaction catalyzed by D201I/D204S required two ions, but over the concentration range of Mg(2+) tested, maximal rate data were fitted to a single binding isotherm. Calcium ions do not support FEN catalysis and inhibit the reactions supported by viable metal cofactors. To establish participation of ions in stabilization of enzyme-substrate complexes, dissociation constants of WT and D201I/D204S-substrate complexes were studied as a function of [Ca(2+)]. At pH 9.3 (maximal rate conditions), Ca(2+) substantially stabilized both complexes. Inhibition of viable cofactor supported reactions of WT, and D201I/D204S T5FENs was biphasic with respect to Ca(2+) and ultimately dependent on 1/[Ca(2+)](2). By varying the concentration of viable metal cofactor, Ca(2+) ions were shown to inhibit competitively displacing two catalytic ions. Combined analyses imply that M2 is not involved in chemical catalysis but plays a role in substrate binding, and thus a two-metal ion mechanism is plausible.     

Escherichia coli DNA helicase I catalyzes a unidirectional and highly processive unwinding reaction

Helicase I has been purified to greater than 95% homogeneity from an F+ strain of Escherichia coli, and characterized as a single-stranded DNA-dependent ATPase and a helicase. The duplex DNA unwinding reaction requires a region of ssDNA for enzyme binding and concomitant nucleoside 5'-triphosphate hydrolysis. All eight predominant nucleoside 5'-triphosphates can satisfy this requirement. Unwinding is unidirectional in the 5' to 3' direction. The length of duplex DNA unwound is independent of protein concentration suggesting that the unwinding reaction is highly processive. Kinetic analysis of the unwinding reaction indicates that the enzyme turns over very slowly from one DNA substrate molecule to another. The ATP hydrolysis reaction is continuous when circular partial duplex DNA substrates are used as DNA effectors. When linear partial duplex substrates are used ATP hydrolysis is barely detectable, although the kinetics of the unwinding reaction on linear partial duplex substrates are identical to those observed using a circular partial duplex DNA substrate. This suggests that ATP hydrolysis fuels continuous translocation of helicase I on circular single-stranded DNA while on linear single stranded DNA the enzyme translocates to the end of the DNA molecule where it must slowly dissociate from the substrate molecule and/or slowly associate with a new substrate molecule, thus resulting in a very low rate of ATP hydrolysis.     

Mechanism whereby proliferating cell nuclear antigen stimulates flap endonuclease 1

Human flap endonuclease 1 (FEN1), an essential DNA replication protein, cleaves substrates with unannealed 5'-tails. FEN1 apparently tracks along the flap from the 5'-end to the cleavage site. Proliferating cell nuclear antigen (PCNA) stimulates FEN1 cleavage 5-50-fold. To determine whether tracking, binding, or cleavage is enhanced by PCNA, we tested a variety of flap substrates. Similar levels of PCNA stimulation occur on both a cleavage-sensitive nicked substrate and a less sensitive gapped substrate. PCNA stimulates FEN1 irrespective of the flap length. Stimulation occurs on a pseudo-Y substrate that exhibits upstream primer-independent cleavage. A pseudo-Y substrate with a sequence requiring an upstream primer for cleavage was not activated by PCNA, suggesting that PCNA does not compensate for substrate features that inhibit cleavage. A biotin.streptavidin conjugation at the 5'-end of a flap structure prevents FEN1 loading. The addition of PCNA does not restore FEN1 activity. These results indicate that PCNA does not direct FEN1 to the cleavage site from solution. Kinetic analyses reveal that PCNA can lower the K(m) for FEN1 by 11-12-fold. Overall, our results indicate that after FEN1 tracks to the cleavage site, PCNA enhances FEN1 binding stability, allowing for greater cleavage efficiency.