DNA binding specificity of MunI restriction endonuclease is controlled by pH and calcium ions: involvement of active site carboxylate residues

Magnetic modulation of lysosomes for cancer therapy

Lysosomes play a central role in biochemical signal transduction and oxidative stress in cells. Inducing lysosome membrane penetration (LMP) to cause lysosomal-dependent cell death (LCD) in tumor cells is an effective strategy for cancer therapy. Chemical drugs can destroy the stability of lysosomes by neutralizing protons within the lysosomes or enhancing the fragility of the lysosomal membranes. However, there remain several unsolved problems of traditional drugs in LMP induction due to insufficient lysosomal targeting, fast metabolism, and toxicity in normal cells. With the development of nanotechnology, magnetic nanoparticles have been demonstrated to target lysosomes naturally, providing a versatile tool for lysosomal modulation. Combined with excellent tissue penetration and spatiotemporal manipulability of magnetic fields, magnetic modulation of lysosomes progresses rapidly in inducing LMP and LCD for cancer therapy. This review comprehensively discussed the strategies of magnetic modulation of lysosomes for cancer therapy. The intrinsic mechanisms of LMP-induced LCD were first introduced. Then, the modulation of lysosomes by diverse physical outputs of magnetic fields was emphatically discussed. Looking forward, this review will shed the light on the prospect of magnetic modulation of lysosomes, inspiring future research of magnetic modulation strategy in cancer therapy. This article is categorized under: Therapeutic Approaches and Drug Discovery > Emerging Technologies Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Nanotechnology Approaches to Biology > Nanoscale Systems in Biology.

Microscopic insight to specificity of metal ion cofactor in DNA cleavage by restriction endonuclease EcoRV

Restriction endonucleases protect bacterial cells against bacteriophage infection by cleaving the incoming foreign DNA into fragments. In presence of Mg²⁺ ions, EcoRV is able to cleave the DNA but not in presence of Ca²⁺ , although the protein binds to DNA in presence of both metal ions. We make an attempt to understand this difference using conformational thermodynamics. We calculate the changes in conformational free energy and entropy of conformational degrees of freedom, like DNA base pair steps and dihedral angles of protein residues in Mg²⁺ (A)-EcoRV-DNA complex compared to Ca²⁺ (S)-EcoRV-DNA complex using all-atom molecular dynamics (MD) trajectories of the complexes. We find that despite conformational stability and order in both complexes, the individual degrees of freedom behave differently in the presence of two different metal ions. The base pairs in cleavage region are highly disordered in Ca²⁺ (S)-EcoRV-DNA compared to Mg²⁺ (A)-EcoRV-DNA. One of the acidic residues ASP90, coordinating to the metal ion in the vicinity of the cleavage site, is conformationally destabilized and disordered, while basic residue LYS92 gets conformational stability and order in Ca²⁺ (S) bound complex than in Mg²⁺ (A) bound complex. The enhanced fluctuations hinder placement of the metal ion in the vicinity of the scissile phosphate of DNA. Similar loss of conformational stability and order in the cleavage region is observed by the replacement of the metal ion. Considering the placement of the metal ion near scissile phosphate as requirement for cleavage action, our results suggest that the changes in conformational stability and order of the base pair steps and the protein residues lead to cofactor sensitivity of the enzyme. Our method based on fluctuations of microscopic conformational variables can be applied to understand enzyme activities in other protein-DNA systems.

Catalytic activity control of restriction endonuclease--triplex forming oligonucleotide conjugates

Targeting of individual genes in complex genomes requires endonucleases of extremely high specificity. To direct cleavage at the unique site(s) in the genome, both naturally occurring and artificial enzymes have been developed. These include homing endonucleases, zinc-finger nucleases, transcription activator-like effector nucleases, and restriction or chemical nucleases coupled to a triple-helix forming oligonucleotide (TFO). The desired cleavage has been demonstrated both in vivo and in vitro for several model systems. However, to limit cleavage strictly to unique sites and avoid undesired reactions, endonucleases with controlled activity are highly desirable. In this study we present a proof-of-concept demonstration of two strategies to generate restriction endonuclease-TFO conjugates with controllable activity. First, we combined the restriction endonuclease caging and TFO coupling procedures to produce a caged MunI-TFO conjugate, which can be activated by UV-light upon formation of a triple helix. Second, we coupled TFO to a subunit interface mutant of restriction endonuclease Bse634I which shows no activity due to impaired dimerization but is assembled into an active dimer when two Bse634I monomers are brought into close proximity by triple helix formation at the targeted site. Our results push the restriction endonuclease-TFO conjugate technology one step closer to potential in vivo applications.

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.

Photocaged variants of the MunI and PvuII restriction enzymes

Regulation of proteins by light is a new and promising strategy for the external control of biological processes. In this study, we demonstrate the ability to regulate the catalytic activity of the MunI and PvuII restriction endonucleases with light. We used two different approaches to attach a photoremovable caging compound, 2-nitrobenzyl bromide (NBB), to functionally important regions of the two enzymes. First, we covalently attached a caging molecule at the dimer interface of MunI to generate an inactive monomer. Second, we attached NBB at the DNA binding site of the single-chain variant of PvuII (scPvuII) to prevent binding and cleavage of the DNA substrate. Upon removal of the caging group by UV irradiation, nearly 50% of the catalytic activity of MunI and 80% of the catalytic activity of PvuII could be restored.

Differences between Ca2+ and Mg2+ in DNA binding and release by the SfiI restriction endonuclease: implications for DNA looping

Many enzymes acting on DNA require Mg(2+) ions not only for catalysis but also to bind DNA. Binding studies often employ Ca(2+) as a substitute for Mg(2+), to promote DNA binding whilst disallowing catalysis. The SfiI endonuclease requires divalent metal ions to bind DNA but, in contrast to many systems where Ca(2+) mimics Mg(2+), Ca(2+) causes SfiI to bind DNA almost irreversibly. Equilibrium binding by wild-type SfiI cannot be conducted with Mg(2+) present as the DNA is cleaved so, to study the effect of Mg(2+) on DNA binding, two catalytically-inactive mutants were constructed. The mutants bound DNA in the presence of either Ca(2+) or Mg(2+) but, unlike wild-type SfiI with Ca(2+), the binding was reversible. With both mutants, dissociation was slow with Ca(2+) but was in one case much faster with Mg(2+). Hence, Ca(2+) can affect DNA binding differently from Mg(2+). Moreover, SfiI is an archetypal system for DNA looping; on DNA with two recognition sites, it binds to both sites and loops out the intervening DNA. While the dynamics of looping cannot be measured with wild-type SfiI and Ca(2+), it becomes accessible with the mutant and Mg(2+).

Dissecting protein-induced DNA looping dynamics in real time

Many proteins that interact with DNA perform or enhance their specific functions by binding simultaneously to multiple target sites, thereby inducing a loop in the DNA. The dynamics and energies involved in this loop formation influence the reaction mechanism. Tethered particle motion has proven a powerful technique to study in real time protein-induced DNA looping dynamics while minimally perturbing the DNA-protein interactions. In addition, it permits many single-molecule experiments to be performed in parallel. Using as a model system the tetrameric Type II restriction enzyme SfiI, that binds two copies of its recognition site, we show here that we can determine the DNA-protein association and dissociation steps as well as the actual process of protein-induced loop capture and release on a single DNA molecule. The result of these experiments is a quantitative reaction scheme for DNA looping by SfiI that is rigorously compared to detailed biochemical studies of SfiI looping dynamics. We also present novel methods for data analysis and compare and discuss these with existing methods. The general applicability of the introduced techniques will further enhance tethered particle motion as a tool to follow DNA-protein dynamics in real time.

Domain organization and functional analysis of type IIS restriction endonuclease Eco31I

Type IIS restriction endonuclease Eco31I harbors a single HNH active site and cleaves both DNA strands close to its recognition sequence, 5'-GGTCTC(1/5). A two-domain organization of Eco31I was determined by limited proteolysis. Analysis of proteolytic fragments revealed that the N-terminal domain of Eco31I is responsible for the specific DNA binding, while the C-terminal domain contains the HNH nuclease-like active site. Gel-shift and gel-filtration experiments revealed that a monomer of the N-terminal domain of Eco31I is able to bind a single copy of cognate DNA. However, in contrast to other studied type IIS enzymes, the isolated catalytic domain of Eco31I was inactive. Steady-state and transient kinetic analysis of Eco31I reactions was inconsistent with dimerization of Eco31I on DNA. Thus, we propose that Eco31I interacts with individual copies of its recognition sequence in its monomeric form and presumably remains a monomer as it cleaves both strands of double-stranded DNA. The domain organization and reaction mechanism established for Eco31I should be common for a group of evolutionary related type IIS restriction endonucleases Alw26I, BsaI, BsmAI, BsmBI and Esp3I that recognize DNA sequences bearing the common pentanucleotide 5'-GTCTC.

Tetrameric restriction enzymes: expansion to the GIY-YIG nuclease family

The GIY-YIG nuclease domain was originally identified in homing endonucleases and enzymes involved in DNA repair and recombination. Many of the GIY-YIG family enzymes are functional as monomers. We show here that the Cfr42I restriction endonuclease which belongs to the GIY-YIG family and recognizes the symmetric sequence 5′-CCGC/GG-3′ (‘/’ indicates the cleavage site) is a tetramer in solution. Moreover, biochemical and kinetic studies provided here demonstrate that the Cfr42I tetramer is catalytically active only upon simultaneous binding of two copies of its recognition sequence. In that respect Cfr42I resembles the homotetrameric Type IIF restriction enzymes that belong to the distinct PD-(E/D)XK nuclease superfamily. Unlike the PD-(E/D)XK enzymes, the GIY-YIG nuclease Cfr42I accommodates an extremely wide selection of metal-ion cofactors, including Mg²⁺, Mn²⁺, Co²⁺, Zn²⁺, Ni²⁺, Cu²⁺ and Ca²⁺. To our knowledge, Cfr42I is the first tetrameric GIY-YIG family enzyme. Similar structural arrangement and phenotypes displayed by restriction enzymes of the PD-(E/D)XK and GIY-YIG nuclease families point to the functional significance of tetramerization.

Unique 31P spectral response to the formation of a specific restriction enzyme-DNA complex

Protein-induced distortion is a dramatic but not universally observed feature of sequence-specific DNA interactions. This is illustrated by the crystal structures of restriction enzyme-DNA complexes: While some of these structures exhibit DNA distortion, others do not. Among the latter is Pvull endonuclease, a small enzyme that is also amenable to NMR spectroscopic studies. Here 31P NMR spectroscopy is applied to demonstrate the unique spectral response of DNA to sequence-specific protein interactions. The 31P NMR spectrum of a noncognate DNA exhibits only spectral broadening upon the addition of enzyme. However, when enzyme is added to target DNA, a number of 31P resonances shift dramatically. The magnitudes of the chemical shifts (2-3 ppm) are among the largest observed. Site-specific substitution with phosphoramidates and phosphorothioates are used analyze these effects. While such spectral features have been interpreted as indicative of DNA backbone distortions, FRET analysis indicates that this does not occur in PvuII-cognate DNA complexes in solution. The distinct 31P spectral signature observed for cognate DNA mirrors that observed for the enzyme, underscoring the unique features of cognate complex formation.

Biochemical and mutational analysis ofEcoRII functional domains reveals evolutionary links between restriction enzymes

The archetypal Type IIE restriction endonuclease EcoRII is a dimer that has a modular structure. DNA binding studies indicate that the isolated C-terminal domain dimer has an interface that binds a single cognate DNA molecule whereas the N-terminal domain is a monomer that also binds a single copy of cognate DNA. Hence, the full-length EcoRII contains three putative DNA binding interfaces: one at the C-terminal domain dimer and two at each of the N-terminal domains. Mutational analysis indicates that the C-terminal domain shares conserved active site architecture and DNA binding elements with the tetrameric restriction enzyme NgoMIV. Data provided here suggest possible evolutionary relationships between different subfamilies of restriction enzymes.

Real-time observation of DNA looping dynamics of Type IIE restriction enzymes NaeI and NarI

Many restriction enzymes require binding of two copies of a recognition sequence for DNA cleavage, thereby introducing a loop in the DNA. We investigated looping dynamics of Type IIE restriction enzymes NaeI and NarI by tracking the Brownian motion of single tethered DNA molecules. DNA containing two endonuclease recognition sites spaced a few 100 bp apart connect small polystyrene beads to a glass surface. The position of a bead is tracked through video microscopy. Protein-mediated looping and unlooping is then observed as a sudden specific change in Brownian motion of the bead. With this method we are able to directly follow DNA looping kinetics of single protein–DNA complexes to obtain loop stability and loop formation times. We show that, in the absence of divalent cations, NaeI induces DNA loops of specific size. In contrast, under these conditions NarI mainly creates non-specific loops, resulting in effective DNA compaction for higher enzyme concentrations. Addition of Ca²⁺ increases the NaeI-DNA loop lifetime by two orders of magnitude and stimulates specific binding by NarI. Finally, for both enzymes we observe exponentially distributed loop formation times, indicating that looping is dominated by (re)binding the second recognition site.

Mva1269I: a monomeric type IIS restriction endonuclease from Micrococcus varians with two EcoRI- and FokI-like catalytic domains

Type II restriction endonuclease Mva1269I recognizes an asymmetric DNA sequence 5'-GAATGCN / -3'/5'-NG / CATTC-3' and cuts top and bottom DNA strands at positions, indicated by the "/" symbol. Most restriction endonucleases require dimerization to cleave both strands of DNA. We found that Mva1269I is a monomer both in solution and upon binding of cognate DNA. Protein fold-recognition analysis revealed that Mva1269I comprises two "PD-(D/E)XK" domains. The N-terminal domain is related to the 5'-GAATTC-3'-specific restriction endonuclease EcoRI, whereas the C-terminal one resembles the nonspecific nuclease domain of restriction endonuclease FokI. Inactivation of the C-terminal catalytic site transformed Mva1269I into a very active bottom strand-nicking enzyme, whereas mutants in the N-terminal domain nicked the top strand, but only at elevated enzyme concentrations. We found that the cleavage of the bottom strand is a prerequisite for the cleavage of the top strand. We suggest that Mva1269I evolved the ability to recognize and to cleave its asymmetrical target by a fusion of an EcoRI-like domain, which incises the bottom strand within the target, and a FokI-like domain that completes the cleavage within the nonspecific region outside the target sequence. Our results have implications for the molecular evolution of restriction endonucleases, as well as for perspectives of engineering new restriction and nicking enzymes with asymmetric target sites.

Cleavage of individual DNA strands by the different subunits of the heterodimeric restriction endonuclease BbvCI

BbvCI cleaves an asymmetric DNA sequence, 5'-CC downward arrow TCAGC-3'/5'-GC downward arrow TGAGG-3', as indicated. While many Type II restriction enzymes consist of identical subunits, BbvCI has two different subunits: R(1), which acts at GC downward arrow TGAGG; and R(2), which acts at CC downward arrow TCAGC. Some mutants of BbvCI with defects in one subunit, either R(1)(-)R(2)(+) or R(1)(+)R(2)(-), cleave only one strand, that attacked by the native subunit. In analytical ultracentrifugation at various concentrations of protein, wild-type and mutant BbvCI enzymes aggregated extensively, but are R(1)R(2) heterodimers at the concentrations used in DNA cleavage reactions. On a plasmid with one recognition site, wild-type BbvCI cleaved both strands before dissociating from the DNA, while the R(1)(-)R(2)(+) and R(1)(+)R(2)(-) mutants acted almost exclusively on their specified strands, albeit at relatively slow rates. During the wild-type reaction, the DNA is cleaved initially in one strand, mainly that targeted by the R(1) subunit. The other strand is then cleaved slowly by R(2) before the enzyme dissociates from the DNA. Hence, the nicked form accumulates as a transient intermediate. This behaviour differs from that of many other restriction enzymes, which cut both strands at equal rates. However, the activities of the R(1)(+) and R(2)(+) subunits in the wild-type enzyme can differ from their activities in the R(1)(+)R(2)(-) and R(1)(-)R(2)(+) mutants. Each active site in BbvCI therefore influences the other.

Conversion of the Tetrameric Restriction Endonuclease Bse634I into a Dimer: Oligomeric Structure–Stability–Function Correlations

The Bse634I restriction endonuclease is a tetramer and belongs to the type IIF subtype of restriction enzymes. It requires two recognition sites for its optimal activity and cleaves plasmid DNA with two sites much faster than a single-site DNA. We show that disruption of the tetramerisation interface of Bse634I by site-directed mutagenesis converts the tetrameric enzyme into a dimer. Dimeric W228A mutant cleaves plasmid DNA containing one or two sites with the same efficiency as the tetramer cleaves the two-site plasmid. Hence, the catalytic activity of the Bse634I tetramer on a single-site DNA is down-regulated due to the cross-talking interactions between the individual dimers. The autoinhibition within the Bse634I tetramer is relieved by bridging two DNA copies into the synaptic complex that promotes fast and concerted cleavage at both sites. Cleavage analysis of the oligonucleotide attached to the solid support revealed that Bse634I is able to form catalytically competent synaptic complexes by bridging two molecules of the cognate DNA, cognate DNA-miscognate DNA and cognate DNA-product DNA. Taken together, our data demonstrate that a single W228A mutation converts a tetrameric type IIF restriction enzyme Bse634I into the orthodox dimeric type IIP restriction endonuclease. However, the stability of the dimer towards chemical denaturants, thermal inactivation and proteolytic degradation are compromised.

Mechanistic insights from the structures of HincII bound to cognate DNA cleaved from addition of Mg2+ and Mn2+

The three-dimensional X-ray crystal structures of HincII bound to cognate DNA containing GTCGAC and Mn(2+) or Mg(2+), at 2.50A and 2.95A resolution, respectively, are presented. In both structures, the DNA is found cleaved, and the positions of the active-site groups, cleaved phosphate group, and 3' oxygen atom of the leaving group are in very similar positions. Two highly occupied Mn(2+) positions are found in each active site of the four crystallographically independent subunit copies in the HincII/DNA/Mn(2+) structure. The manganese ion closest to the previously identified single Ca(2+) position of HincII is shifted 1.7A and has lost direct ligation to the active-site aspartate residue, Asp127. A Mn(2+)-ligated water molecule in a position analogous to that seen in the HincII/DNA/Ca(2+) structure, and proposed to be the attacking nucleophile, is beyond hydrogen bonding distance from the active-site lysine residue, Lys129, but remains within hydrogen bonding distance from the proRp oxygen atom of the phosphate group 3' to the scissile phosphate group. In addition, the position of the cleaved phosphate group is on the opposite side of the axis connecting the two metal ions relative to that found in the BamHI/product DNA/Mn(2+) structure. Mechanistic implications are discussed, and a model for the two-metal-ion mechanism of DNA cleavage by HincII is proposed.

Characterization of a novel DNA minor-groove complex

Many dicationic amidine compounds bind in the DNA minor groove and have excellent biological activity against a range of infectious diseases. Para-substituted aromatic diamidines such as furamidine, which is currently being tested against trypanosomiasis in humans, and berenil, which is used in animals, are typical examples of this class. Recently, a meta-substituted diamidine, CGP 40215A, has been found to have excellent antitrypanosomal activity. The compound has a linear, conjugated linking group that can be protonated under physiological conditions when the compound interacts with DNA. Structural and molecular dynamics analysis of the DNA complex indicated an unusual AT-specific complex that involved water-mediated H-bonds between one amidine of the compound and DNA bases at the floor of the minor groove. To investigate this unique system in more detail DNase I footprinting, surface plasmon resonance biosensor techniques, linear dichroism, circular dichroism, ultraviolet-visible spectroscopy, and additional molecular dynamics simulations have been conducted. Spectrophotometric titrations of CGP 40215A binding to poly(dAT)(2) have characteristics of DNA-binding-induced spectral changes as well as effects due to binding-induced protonation of the compound linker. Both footprinting and surface plasmon resonance results show that this compound has a high affinity for AT-rich sequences of DNA but very weak binding to GC sequences. The dissociation kinetics of the CGP 40215A-DNA complex are much slower than with similar diamidines such as berenil. The linear dichroism results support a minor-groove complex for the compound in AT DNA sequences. Molecular dynamics studies complement the structural analysis and provide a clear picture of the importance of water in mediating the dynamic interactions between the ligand and the DNA bases in the minor groove.

Ca(2+)-mediated site-specific DNA cleavage and suppression of promiscuous activity of KpnI restriction endonuclease

The characteristic feature of type II restriction endonucleases (REases) is their exquisite sequence specificity and obligate Mg(2+) requirement for catalysis. Efficient cleavage of DNA only in the presence of Ca(2+) ions, comparable with that of Mg(2+), is previously not described. Most intriguingly, KpnI REase exhibits Ca(2+)-dependent specific DNA cleavage. Moreover, the enzyme is highly promiscuous in its cleavage pattern on plasmid DNAs in the presence of Mn(2+) or Mg(2+), with the complete suppression of promiscuous activity in the presence of Ca(2+). KpnI methyltransferase does not exhibit promiscuous activity unlike its cognate REase. The REase binds to oligonucleotides containing canonical and mapped noncanonical sites with comparable affinities. However, the extent of cleavage is varied depending on the metal ion and the sequence. The ability of the enzyme to be promiscuous or specific may reflect an evolutionary design. Based on the results, we suggest that the enzyme KpnI represents an REase evolving to attain higher sequence specificity from an ancient nonspecific nuclease.

DNA recognition by the EcoRV restriction endonuclease probed using base analogues

The EcoRV restriction endonuclease recognises palindromic GATATC sequences and cuts between the central T and dA bases in a reaction that has an absolute requirement for a divalent metal ion, physiologically Mg(2+). Use has been made of base analogues, which delete hydrogen bonds between the protein and DNA (or hydrophobic interactions in the case of the 5-CH(3) group of thymine), to evaluate the roles of the outer two base-pairs (GATATC) in DNA recognition. Selectivity arises at both the binding steps leading to the formation of the enzyme-DNA-metal ion ternary complex (assayed by measuring the dissociation constant in the presence of the non-reactive metal Ca(2+)) and the catalytic step (evaluated using single-turnover hydrolysis in the presence of Mg(2+)), with each protein-DNA contact contributing to recognition. With the A:T base-pair, binding was reduced by the amount expected for the simple loss of a single contact; much more severe effects were observed with the G:C base-pair, suggesting additional conformational perturbation. Most of the modified bases lowered the rate of hydrolysis; furthermore, the presence of an analogue in one strand of the duplex diminished cutting at the second, unmodified strand, indicative of communication between DNA binding and the active site. The essential metal ion Mg(2+) plays a key role in mediating interactions between the DNA binding site and active centre and in many instances rescue of hydrolysis was seen with Mn(2+). It is suggested that contacts between the GATATC site are required for tight binding and for the correct assembly of metal ions and bound water at the catalytic site, functions important in providing acid/base catalysis and transition state stabilisation.

Type II restriction endonucleases

Type II restriction endonucleases have emerged as important paradigms for the study of protein-nucleic acid interactions. This is due to their ability to catalyse phosphodiester bond cleavage with very large rate enhancements while also maintaining exquisite sequence selectivities. The principles and methods developed to analyze site-specific binding and catalysis for restriction endonucleases can be applied to other enzymes which also operate on nucleic acids. This paper reviews biochemical and structural approaches to characterization of these enzymes, with particular attention to the multiple crucial roles of divalent metal ions, the possibilities for use of alternative substrates in binding and catalytic experiments, the strategies for exploring the detailed chemistry of phosphoryl transfer, and the use of X-ray crystallography to provide descriptions of conformational pathways at specific, nonspecific, and noncognate DNA sites.

Alternative arrangements of catalytic residues at the active sites of restriction enzymes

A catalytic sequence motif PDX10-30(E/D)XK is found in many restriction enzymes. On the basis of sequence similarities and mapping of the conserved residues to the crystal structure of NgoMIV we suggest that residues D160, K182, R186, R188 and E195 contribute to the catalytic/DNA binding site of the Ecl18kI restriction endonuclease. Mutational analysis confirms the functional significance of the conserved residues of Ecl18kI. Therefore, we conclude that the active site motif 159VDX21KX12E of Ecl18kI differs from the canonical PDX10-30(E/D)XK motif characteristic for most of the restriction enzymes. Moreover, we propose that two subfamilies of endonucleases Ecl18kI/PspGI/EcoRII and Cfr10I/Bse634I/NgoMIV, specific, respectively, for CCNGG/CCWGG and RCCGGY/GCCGGC sites, share conserved active site architecture and DNA binding elements.

DNA binding and recognition by the IIs restriction endonuclease MboII

The type IIs restriction endonuclease MboII recognizes nonsymmetrical GAAGA sites, cutting 8 (top strand) and 7 (bottom strand) bases to the right. Gel retardation showed that MboII bound specifically to GAAGA sequences, producing two distinct complexes each containing one MboII and one DNA molecule. Interference analysis indicated that the initial species formed, named complex 1, comprised an interaction between the enzyme and the GAAGA target. Complex 2 involved interaction of the protein with both the GAAGA and the cutting sites. Only in the presence of divalent metal ions such as Ca(2+) is the conversion of complex 1 to 2 rapid. Additionally, a very retarded complex was seen with Ca(2+), possibly a (MboII)(2)-(DNA)(2) complex. Plasmids containing a single GAAGA site were hydrolyzed slowly by MboII. Plasmids containing two sites were cut far more rapidly, suggesting that the enzyme requires two recognition sites in the same DNA molecule for efficient hydrolysis. MboII appears to have a mechanism similar to the best characterized type IIs enzyme, FokI. Both enzymes initially bind DNA as monomers, followed by dimerization to give an (enzyme)(2)-(DNA)(2) complex. Dimerization is efficient only when the two target sites are located in the same DNA molecule and requires divalent metal ions.

Structure and function of type II restriction endonucleases

More than 3000 type II restriction endonucleases have been discovered. They recognize short, usually palindromic, sequences of 4-8 bp and, in the presence of Mg(2+), cleave the DNA within or in close proximity to the recognition sequence. The orthodox type II enzymes are homodimers which recognize palindromic sites. Depending on particular features subtypes are classified. All structures of restriction enzymes show a common structural core comprising four beta-strands and one alpha-helix. Furthermore, two families of enzymes can be distinguished which are structurally very similar (EcoRI-like enzymes and EcoRV-like enzymes). Like other DNA binding proteins, restriction enzymes are capable of non-specific DNA binding, which is the prerequisite for efficient target site location by facilitated diffusion. Non-specific binding usually does not involve interactions with the bases but only with the DNA backbone. In contrast, specific binding is characterized by an intimate interplay between direct (interaction with the bases) and indirect (interaction with the backbone) readout. Typically approximately 15-20 hydrogen bonds are formed between a dimeric restriction enzyme and the bases of the recognition sequence, in addition to numerous van der Waals contacts to the bases and hydrogen bonds to the backbone, which may also be water mediated. The recognition process triggers large conformational changes of the enzyme and the DNA, which lead to the activation of the catalytic centers. In many restriction enzymes the catalytic centers, one in each subunit, are represented by the PD. D/EXK motif, in which the two carboxylates are responsible for Mg(2+) binding, the essential cofactor for the great majority of enzymes. The precise mechanism of cleavage has not yet been established for any enzyme, the main uncertainty concerns the number of Mg(2+) ions directly involved in cleavage. Cleavage in the two strands usually occurs in a concerted fashion and leads to inversion of configuration at the phosphorus. The products of the reaction are DNA fragments with a 3'-OH and a 5'-phosphate.

The energetics of the interaction of BamHI endonuclease with its recognition site GGATCC

The interaction of BamHI endonuclease with DNA has been studied crystallographically, but has not been characterized rigorously in solution. The enzyme binds in solution as a homodimer to its recognition site GGATCC. Only six base-pairs are directly recognized, but binding affinity (in the absence of the catalytic cofactor Mg(2+)) increases 5400-fold as oligonucleotide length increases from 10 to 14 bp. Binding is modulated by sequence context outside the recognition site, varying about 30-fold from the bes t (GTG or TAT) to the worst (CGG) flanking triplets. BamHI, EcoRI and EcoRV endonucleases all have different context preferences, suggesting that context affects binding by influencing the free energy levels of the complexes rather than that of the free DNA. Ethylation interference footprinting in the absence of divalent metal shows a localized and symmetrical pattern of phosphate contacts, with strong contacts at NpNpNpGGApTCC. In the presence of Mg(2+), first-order cleavage rate constants are identical in the two GGA half-sites, are the same for the two nicked intermediates and are unaffected by substrate length in the range 10-24 bp. DNA binding is strongly enhanced by mutations D94N, E111A or E113K, by binding of Ca(2+) at the active site, or by deletion of the scissile phosphate GpGATCC, indicating that a cluster of negative charges at the catalytic site contributes at least 3-4 kcal/mol of unfavorable binding free energy. This electrostatic repulsion destabilizes the enzyme-DNA complex and favors metal ion binding and progression to the transition state for cleavage.

Catalytic efficiency and sequence selectivity of a restriction endonuclease modulated by a distal manganese ion binding site

Crystal structures of EcoRV endonuclease bound in a ternary complex with cognate duplex DNA and manganese ions have previously revealed an Mn(2+)-binding site located between the enzyme and the DNA outside of the dyad-symmetric GATATC recognition sequence. In each of the two enzyme subunits, this metal ion bridges between a distal phosphate group of the DNA and the imidazole ring of His71. The new metal- binding site is specific to Mn(2+) and is not occupied in ternary cocrystal structures with either Mg(2+) or Ca(2+). Characterization of the H71A and H71Q mutants of EcoRV now demonstrates that these distal Mn(2+) sites significantly modulate activity toward both cognate and non-cognate DNA substrates. Single-turnover and steady-state kinetic analyses show that removal of the distal site in the mutant enzymes increases Mn(2+)-dependent cleavage rates of specific substrates by tenfold. Conversely, the enhancement of non-cognate cleavage at GTTATC sequences by Mn(2+) is significantly attenuated in the mutants. As a consequence, under Mn(2+) conditions EcoRV-H71A and EcoRV-H71Q are 100 to 700-fold more specific than the wild-type enzyme for cognate DNA relative to the GTTATC non-cognate site. These data reveal a strong dependence of DNA cleavage efficiency upon metal ion-mediated interactions located some 20 A distant from the scissile phosphodiester linkages. They also show that discrimination of cognate versus non-cognate DNA sequences by EcoRV depends in part on contacts with the sugar-phosphate backbone outside of the target site.

Interaction of the E. coli DNA G:T-mismatch endonuclease (vsr protein) with oligonucleotides containing its target sequence

The Escherichia coli vsr endonuclease recognises G:T base-pair mismatches in double-stranded DNA and initiates a repair pathway by hydrolysing the phosphate group 5' to the incorrectly paired T. The enzyme shows a preference for G:T mismatches within a particular sequence context, derived from the recognition site of the E. coli dcm DNA-methyltransferase (CC[A/T]GG). Thus, the preferred substrate for the vsr protein is (CT[A/T]GG), where the underlined T is opposed by a dG base. This paper provides quantitative data for the interaction of the vsr protein with a number of oligonucleotides containing G:T mismatches. Evaluation of specificity constant (k(st)/K(D); k(st)=rate constant for single turnover, K(D)=equilibrium dissociation constant) confirms vsr's preference for a G:T mismatch within a hemi-methylated dcm sequence, i.e. the best substrate is a duplex (both strands written in the 5'-3' orientation) composed of CT[A/T]GG and C(5Me)C[T/A]GG. Conversion of the mispaired T (underlined) to dU or the d(5Me)C to dC gave poorer substrates. No interaction was observed with oligonucleotides that lacked a G:T mismatch or did not possess a dcm sequence. An analysis of the fraction of active protein, by "reverse-titration" (i.e. adding increasing amounts of DNA to a fixed amount of protein followed by gel-mobility shift analysis) showed that less than 1% of the vsr endonuclease was able to bind to the substrate. This was confirmed using "competitive titrations" (where competitor oligonucleotides are used to displace a (32)P-labelled nucleic acid from the vsr protein) and burst kinetic analysis. This result is discussed in the light of previous in vitro and in vivo data which indicate that the MutL protein may be needed for full vsr activity.

DNA cleavage by the EcoRV restriction endonuclease: pH dependence and proton transfers in catalysis

To characterise the pH dependence of phosphodiester hydrolysis by the EcoRV endonuclease in the presence of Mn2+, single turnover reactions on a 12 bp DNA substrate were examined by stopped-flow and quench-flow methods between pH 6.0 and 8.5. At each pH value, the apparent rate constants for phosphodiester hydrolysis increased hyperbolically with the concentration of MnCl2, thus allowing values to be determined for the intrinsic rate constant at saturation with Mn2+ and the equilibrium dissociation constant for Mn2+. The equilibrium constants showed no systematic variation across the pH range tested, while the rate constants increased steeply with increasing pH up to an asymptote above pH 7.5. At low pH conditions, the gradient of a plot of log (rate constant) against pH approached a value of 2. DNA cleavage by EcoRV thus requires the de-protonation of two acidic groups. To determine whether aspartate 36 is one of the groups, mutants of EcoRV were made with other amino acid residues at position 36. Glutamate caused a partial loss of activity, while all other replacements gave near-zero activities. In contrast to wild-type EcoRV, the mutant with glutamate required the de-protonation of only one acidic group for DNA cleavage. A mechanism for EcoRV is proposed in which the water molecule that hydrolyses the phosphodiester bond is de-protonated by two Bronsted bases, probably the ionised forms of aspartate 36 and glutamate 45.

Genomic structure of the human DNA methyltransferase gene

We determined the genomic structure of the gene encoding human DNA methyltransferase (DNA MTase). Six overlapping human genomic DNA clones which include all of the known cDNA sequence were isolated. Analysis of these clones demonstrates that the human DNA MTase gene consists of at least 40 exons and 39 introns spanning a distance of 60 kilobases. Elucidation of the chromosomal organization of the human DNA MTase gene provides the template for future structure-function analysis of the properties of mammalian DNA MTase.

Reactions of the eco RV restriction endonuclease with fluorescent oligodeoxynucleotides: identical equilibrium constants for binding to specific and non-specific DNA

The EcoRV restriction endonuclease cleaves DNA specifically at its recognition sequence in the presence of magnesium ions, but several studies have indicated that it binds to DNA in the absence of Mg2+ without any preference for its recognition site. However, specific binding to the recognition site has also been reported. To distinguish between these reports, oligodeoxynucleotides were tagged with either dansyl or eosin fluorophores at their 5' termini and annealed to form duplexes of 12 to 16 base-pairs. For each length of duplex, one derivative had the EcoRV recognition sequence while another lacked this sequence. For the duplexes with the recognition site, the fluorophores had no effect on DNA cleavage rates by EcoRV in the presence of Mg2+. The binding of the specific and non-specific duplexes to EcoRV in the absence of Mg2+ was measured by fluorescence resonance energy transfer and by fluorescence depolarization. In both procedures, the signal from the specific complex differed from the complex with non-specific DNA, with the depolarization data indicating that non-specific DNA bound to EcoRV retains a higher rotational freedom than specific DNA. Even so, the equilibrium constant for the binding of specific DNA was identical, within error limits, to that for non-specific DNA.