The crystal structure of EcoRV endonuclease and of its complexes with cognate and non-cognate DNA fragments

Identification of a base-specific contact between the restriction endonuclease SsoII and its recognition sequence by photocross-linking

A target sequence-specific DNA binding region of the restriction endonuclease Sso II was identified by photocross-linking with an oligodeoxynucleotide duplex which was substituted with 5-iododeoxy-uridine (5-IdU) at the central position of the Sso II recognition site (CCNGG). For this purpose the Sso II-DNA complex was irradiated with a helium/cadmium laser (325 nm). The cross-linking yield obtained was approximately 50%. In the presence of excess unmodified oligodeoxynucleotide or with oligode-oxynucleotides substituted with 5-IdU elsewhere, no cross-linking was observed, indicating the specificity of the cross-linking reaction. The cross-linked Sso II-oligodeoxynucleotide complex was digested with chymotrypsin, a cross-linked peptide-oligodeoxy-nucleotide complex isolated and the site of cross-linking identified by Edman sequencing to be Trp61. In line with this identification is the finding that the W61A variant cannot be cross-linked with the IdU-substituted oligodeoxynucleotide, shows a decrease in affinity towards DNA and is inactive in cleavage. It is concluded that the region around Trp61 is involved in specific binding of Sso II to its DNA substrate.

Cloning, expression, and purification of a thermostable nonhomodimeric restriction enzyme, BslI

BslI is a thermostable type II restriction endonuclease with interrupted recognition sequence CCNNNNN/NNGG (/, cleavage position). The BslI restriction-modification system from Bacillus species was cloned and expressed in Escherichia coli. The system is encoded by three genes: the 2,739-bp BslI methylase gene (bslIM), the bslIRalpha gene, and the bslIRbeta gene. The alpha and beta subunits of BslI can be expressed independently in E. coli in the absence of BslI methylase (M.BslI) protection. BslI endonuclease activity can be reconstituted in vitro by mixing the two subunits together. Gel filtration chromatography and native polyacrylamide gel electrophoresis indicated that BslI forms heterodimers (alphabeta), heterotetramers (alpha(2)beta(2)), and possibly oligomers in solution. Two beta subunits can be cross-linked by a chemical cross-linking agent, indicating formation of heterotetramer BslI complex (alpha(2)beta(2)). In DNA mobility shift assays, neither subunit alone can bind DNA. DNA mobility shift activity was detected after mixing the two subunits together. Because of the symmetric recognition sequence of the BslI endonuclease, we propose that its active form is alpha(2)beta(2). M.BslI contains nine conserved motifs of N-4 cytosine DNA methylases within the beta group of aminomethyltransferase. Synthetic duplex deoxyoligonucleotides containing cytosine hemimethylated or fully methylated at N-4 in BslI sites in the first or second cytosine are resistant to BslI digestion. C-5 methylation of the second cytosine on both strands within the recognition sequence also renders the site refractory to BslI digestion. Two putative zinc fingers are found in the alpha subunit of BslI endonuclease.

Crowding effects on EcoRV kinetics and binding

The cytosol of the cell contains high concentrations of small and large macromolecules, but experimental data are often obtained in dilute solutions that do not reflect in vivo conditions. We have studied the crowding effect that large macromolecules have on EcoRV cleavage by adding high-molecular-weight Ficoll 70 to reaction solutions. Results indicate that Ficoll has surprisingly little effect on overall EcoRV reaction velocity because of offsetting increases in V(max) and K(m), and stronger nonspecific binding. The changes in measured parameters can largely be attributed to the excluded volume effects on reactant activities and the slowing of protein diffusion. Covolume reduction upon binding appears to reinforce nonspecific binding strength, and k(cat) appears to be slowed by stronger nonspecific binding, which slows product release. The data also suggest that effective Ficoll particle volume decreases as its concentration increases above a few weight percent, which may be due to Ficoll interpenetration or compression.

Thermodynamics of T cell receptor binding to peptide-MHC: evidence for a general mechanism of molecular scanning

Antigen-dependent activation of T lymphocytes requires T cell receptor (TCR)-mediated recognition of specific peptides, together with the MHC molecules to which they are bound. To achieve this recognition in a reasonable time frame, the TCR must scan and discriminate rapidly between thousands of MHC molecules differing from each other only in their bound peptides. Kinetic analysis of the interaction between a TCR and its cognate peptide-MHC complex indicates that both association and dissociation depend heavily on the temperature, indicating the presence of large energy barriers in both phases. Thermodynamic analysis reveals changes in heat capacity and entropy that are characteristic of protein-ligand associations in which local folding is coupled to binding. Such an "induced-fit" mechanism is characteristic of sequence-specific DNA-binding proteins that must also recognize specific ligands in the presence of a high background of competing elements. Here, we propose that induced fit may endow the TCR with its requisite discriminatory capacity and suggest a model whereby the loosely structured antigen-binding loops of the TCR rapidly explore peptide-MHC complexes on the cell surface until some critical structural complementarity is achieved through localized folding transitions. We further suggest that conformational changes, implicit in this model, may also propagate beyond the TCR antigen-binding site and directly affect self-association of ligated TCRs or TCR-CD3 interactions required for signaling.

Identification of the endonuclease domain encoded by R2 and other site-specific, non-long terminal repeat retrotransposable elements

The non-long terminal repeat (LTR) retrotransposon, R2, encodes a sequence-specific endonuclease responsible for its insertion at a unique site in the 28S rRNA genes of arthropods. Although most non-LTR retrotransposons encode an apurinic-like endonuclease upstream of a common reverse transcriptase domain, R2 and many other site-specific non-LTR elements do not (CRE1 and 2, SLACS, CZAR, Dong, R4). Sequence comparison of these site-specific elements has revealed that the region downstream of their reverse transcriptase domain is conserved and shares sequence features with various prokaryotic restriction endonucleases. In particular, these non-LTR elements have a Lys/Arg-Pro-Asp-X12-14aa-Asp/Glu motif known to lie near the scissile phosphodiester bonds in the protein-DNA complexes of restriction enzymes. Site-directed mutagenesis of the R2 protein was used to provide evidence that this motif is also part of the active site of the endonuclease encoded by this element. Mutations of this motif eliminate both DNA-cleavage activities of the R2 protein: first-strand cleavage in which the exposed 3' end is used to prime reverse transcription of the RNA template and second-strand cleavage, which occurs after reverse transcription. The general organization of the R2 protein appears similar to the type IIS restriction enzyme, FokI, in which specific DNA binding is controlled by a separate domain located amino terminal to the cleavage domain. Previous phylogenetic analysis of their reverse transcriptase domains has indicated that the non-LTR elements identified here as containing restriction-like endonucleases are the oldest lineages of non-LTR elements, suggesting a scenario for the evolution of non-LTR elements.

Solution structure of the HMG protein NHP6A and its interaction with DNA reveals the structural determinants for non-sequence-specific binding

NHP6A is a chromatin-associated protein from Saccharomyces cerevisiae belonging to the HMG1/2 family of non-specific DNA binding proteins. NHP6A has only one HMG DNA binding domain and forms relatively stable complexes with DNA. We have determined the solution structure of NHP6A and constructed an NMR-based model structure of the DNA complex. The free NHP6A folds into an L-shaped three alpha-helix structure, and contains an unstructured 17 amino acid basic tail N-terminal to the HMG box. Intermolecular NOEs assigned between NHP6A and a 15 bp 13C,15N-labeled DNA duplex containing the SRY recognition sequence have positioned the NHP6A HMG domain onto the minor groove of the DNA at a site that is shifted by 1 bp and in reverse orientation from that found in the SRY-DNA complex. In the model structure of the NHP6A-DNA complex, the N-terminal basic tail is wrapped around the major groove in a manner mimicking the C-terminal tail of LEF1. The DNA in the complex is severely distorted and contains two adjacent kinks where side chains of methionine and phenylalanine that are important for bending are inserted. The NHP6A-DNA model structure provides insight into how this class of architectural DNA binding proteins may select preferential binding sites.

Crosslinking the EcoRV restriction endonuclease across the DNA-binding site reveals transient intermediates and conformational changes of the enzyme during DNA binding and catalytic turnover

EcoRV completely encircles bound DNA with two loops, forming the entry and exit gate for the DNA substrate. These loops were crosslinked generating CL-EcoRV which binds and releases linear DNA only slowly, because threading linear DNA into and out of the DNA-binding 'tunnel' of CL-EcoRV is not very effective. If the crosslinking reaction is carried out with a circular bound DNA, CL-EcoRV is hyperactive towards the trapped substrate which is cleaved very quickly but not very accurately. CL-EcoRV also binds to, but does not cleave, circular DNA when added from the outside, because it cannot enter the active site. Based on these results a two-step binding model is proposed for EcoRV: initial DNA binding occurs at the outer side of the loops before the gate opens and then the DNA is transferred to the catalytic center.

Metal ion-mediated substrate-assisted catalysis in type II restriction endonucleases

The 2.15-A resolution cocrystal structure of EcoRV endonuclease mutant T93A complexed with DNA and Ca2+ ions reveals two divalent metals bound in one of the active sites. One of these metals is ligated through an inner-sphere water molecule to the phosphate group located 3' to the scissile phosphate. A second inner-sphere water on this metal is positioned approximately in-line for attack on the scissile phosphate. This structure corroborates the observation that the pro-SP phosphoryl oxygen on the adjacent 3' phosphate cannot be modified without severe loss of catalytic efficiency. The structural equivalence of key groups, conserved in the active sites of EcoRV, EcoRI, PvuII, and BamHI endonucleases, suggests that ligation of a catalytic divalent metal ion to this phosphate may occur in many type II restriction enzymes. Together with previous cocrystal structures, these data allow construction of a detailed model for the pretransition state configuration in EcoRV. This model features three divalent metal ions per active site and invokes assistance in the bond-making step by a conserved lysine, which stabilizes the attacking hydroxide ion nucleophile.

Crystal structure of restriction endonuclease BglI bound to its interrupted DNA recognition sequence

The crystal structure of the type II restriction endonuclease BglI bound to DNA containing its specific recognition sequence has been determined at 2.2 A resolution. This is the first structure of a restriction endonuclease that recognizes and cleaves an interrupted DNA sequence, producing 3' overhanging ends. BglI is a homodimer that binds its specific DNA sequence with the minor groove facing the protein. Parts of the enzyme reach into both the major and minor grooves to contact the edges of the bases within the recognition half-sites. The arrangement of active site residues is strikingly similar to other restriction endonucleases, but the co-ordination of two calcium ions at the active site gives new insight into the catalytic mechanism. Surprisingly, the core of a BglI subunit displays a striking similarity to subunits of EcoRV and PvuII, but the dimer structure is dramatically different. The BglI-DNA complex demonstrates, for the first time, that a conserved subunit fold can dimerize in more than one way, resulting in different DNA cleavage patterns.

Structure of FokI has implications for DNA cleavage

FokI is a member an unusual class of restriction enzymes that recognize a specific DNA sequence and cleave nonspecifically a short distance away from that sequence. FokI consists of an N-terminal DNA recognition domain and a C-terminal cleavage domain. The bipartite nature of FokI has led to the development of artificial enzymes with novel specificities. We have solved the structure of FokI to 2.3 A resolution. The structure reveals a dimer, in which the dimerization interface is mediated by the cleavage domain. Each monomer has an overall conformation similar to that found in the FokI-DNA complex, with the cleavage domain packing alongside the DNA recognition domain. In corroboration with the cleavage data presented in the accompanying paper in this issue of Proceedings, we propose a model for FokI DNA cleavage that requires the dimerization of FokI on DNA to cleave both DNA strands.

Cloning and thermostability of TaqI endonuclease isoschizomers from Thermus species SM32 and Thermus filiformis Tok6A1

Two TaqI endonuclease (hereafter referred to as TaqI) isoschizomer genes, tsp32IR from Thermus species SM32 of Azores and tfiTok6A1I from T. filiformis Tok6A1 of New Zealand, were cloned in Escherichia coli. The overexpressed enzymes were partly purified and their thermostability was determined. In the medium-salt buffer, Tsp32IR, TfiTok6A1I and one previously cloned TaqI isoschizomer (TthHB8I) were more thermostable than TaqI. Tsp32IR remained partly active up to 90 degreesC in the low-salt buffer. Six amino acid residues that are identical in the three high thermostability isoschizomers (Tsp32IR, TfiTok6A1I and TthHB8I) but differ in TaqI might provide added rigidity for thermostabilization. These include four proline residues located in or near loop regions, and one alanine and one arginine located at helix regions in the predicted TaqI endonuclease secondary structure. The possible role of these residues in thermostabilization was evaluated by mutagenizing the TaqI enzyme. Mutants generated at these six positions were less thermostable than wild-type TaqI. The results suggest that the surrounding sequence or structural context might be as important as the mutation itself.

Structural, functional, and evolutionary relationships between lambda-exonuclease and the type II restriction endonucleases

lambda-exonuclease participates in DNA recombination and repair. It binds a free end of double-stranded DNA and degrades one strand in the 5' to 3' direction. The primary sequence does not appear to be related to any other protein, but the crystal structure shows part of lambda-exonuclease to be similar to the type II restriction endonucleases PvuII and EcoRV. There is also a weaker correspondence with EcoRI, BamHI, and Cfr10I. The structure comparisons not only suggest that these enzymes all share a similar catalytic mechanism and a common structural ancestor but also provide strong evidence that the toroidal structure of lambda-exonuclease encircles its DNA substrate during hydrolysis.

Crystal structure of an engineered Cro monomer bound nonspecifically to DNA: possible implications for nonspecific binding by the wild-type protein

The structure has been determined at 3.0 A resolution of a complex of engineered monomeric Cro repressor with a seven-base pair DNA fragment. Although the sequence of the DNA corresponds to the consensus half-operator that is recognized by each subunit of the wild-type Cro dimer, the complex that is formed in the crystals by the isolated monomer appears to correspond to a sequence-independent mode of association. The overall orientation of the protein relative to the DNA is markedly different from that observed for Cro dimer bound to a consensus operator. The recognition helix is rotated 48 degrees further out of the major groove, while the turn region of the helix-turn-helix remains in contact with the DNA backbone. All of the direct base-specific interactions seen in the wild-type Cro-operator complex are lost. Virtually all of the ionic interactions with the DNA backbone, however, are maintained, as is the subset of contacts between the DNA backbone and a channel on the protein surface. Overall, 25% less surface area is buried at the protein DNA interface than for half of the wild-type Cro-operator complex, and the contacts are more ionic in character due to a reduction of hydrogen bonding and van der Waals interactions. Based on this crystal structure, model building was used to develop a possible model for the sequence-nonspecific interaction of the wild-type Cro dimer with DNA. In the sequence-specific complex, the DNA is bent, the protein dimer undergoes a large hinge-bending motion relative to the uncomplexed form, and the complex is twofold symmetric. In contrast, in the proposed nonspecific complex the DNA is straight, the protein retains a conformation similar to the apo form, and the complex lacks twofold symmetry. The model is consistent with thermodynamic, chemical, and mutagenic studies, and suggests that hinge bending of the Cro dimer may be critical in permitting the transition from the binding of protein at generic sites on the DNA to binding at high affinity operator sites.

DNA bending: the prevalence of kinkiness and the virtues of normality

DNA bending in 86 complexes with sequence-specific proteins has been examined using normal vector plots, matrices of normal vector angles between all base pairs in the helix, and one-digit roll/slide/twist tables. FREEHELIX, a new program especially designed to analyze severely bent and kinked duplexes, generates the foregoing quantities plus local roll, tilt, twist, slide, shift and rise parameters that are completely free of any assumptions about an overall helix axis. In nearly every case, bending results from positive roll at pyrimidine-purine base pair steps: C-A (= T-G), T-A, or less frequently C-G, in a direction that compresses the major groove. Normal vector plots reveal three well-defined types of bending among the 86 examples: (i) localized kinks produced by positive roll at one or two discrete base pairs steps, (ii) three-dimensional writhe resulting from positive roll at a series of adjacent base pairs steps, or (iii) continuous curvature produced by alternations of positive and negative roll every 5 bp, with side-to-side zig-zag roll at intermediate position. In no case is tilt a significant component of the bending process. In sequences with two localized kinks, such as CAP and IHF, the dihedral angle formed by the three helix segments is a linear function of the number of base pair steps between kinks: dihedral angle = 36 degrees x kink separation. Twenty-eight of the 86 examples can be described as major bends, and significant elements in the recognition of a given base sequence by protein. But even the minor bends play a role in fine-tuning protein/DNA interactions. Sequence-dependent helix deformability is an important component of protein/DNA recognition, alongside the more generally recognized patterns of hydrogen bonding. The combination of FREEHELIX, normal vector plots, full vector angle matrices, and one-digit roll/slide/twist tables affords a rapid and convenient method for assessing bending in DNA.

Structural basis for MutH activation in E.coli mismatch repair and relationship of MutH to restriction endonucleases

MutS, MutL and MutH are the three essential proteins for initiation of methyl-directed DNA mismatch repair to correct mistakes made during DNA replication in Escherichia coli. MutH cleaves a newly synthesized and unmethylated daughter strand 5' to the sequence d(GATC) in a hemi-methylated duplex. Activation of MutH requires the recognition of a DNA mismatch by MutS and MutL. We have crystallized MutH in two space groups and solved the structures at 1.7 and 2.3 A resolution, respectively. The active site of MutH is located at an interface between two subdomains that pivot relative to one another, as revealed by comparison of the crystal structures, and this presumably regulates the nuclease activity. The relative motion of the two subdomains in MutH correlates with the position of a protruding C-terminal helix. This helix appears to act as a molecular lever through which MutS and MutL may communicate the detection of a DNA mismatch and activate MutH. With sequence homology to Sau3AI and structural similarity to PvuII endonuclease, MutH is clearly related to these enzymes by divergent evolution, and this suggests that type II restriction endonucleases evolved from a common ancestor.

2-Aminopurine as a fluorescent probe for DNA base flipping by methyltransferases

DNA base flipping, which was first observed for the C5-cytosine DNA methyltransferase M. Hha I, results in a complete removal of the stacking interactions between the target base and its neighbouring bases. We have investigated whether duplex oligodeoxynucleotides containing the fluorescent base analogue 2-aminopurine can be used to sense DNA base flipping. Using M. Hha I as a paradigm for a base flipping enzyme, we find that the fluorescence intensity of duplex oligodeoxynucleotides containing 2-aminopurine at the target site is dramatically enhanced (54-fold) in the presence of M. Hha I. Duplex oligodeoxynucleotides containing 2-aminopurine adjacent to the target cytosine show little fluorescence increase upon addition of M. Hha I. These results clearly demonstrate that duplex oligodeoxynucleotides containing 2-aminopurine at the target site can serve as fluorescence probes for base flipping. Another enzyme hypothesized to use a base flipping mechanism is the N6-adenine DNA methyltransferase M. Taq I. Addition of M. Taq I to duplex oligodeoxynucleotides bearing 2-aminopurine at the target position, also results in a strongly enhanced fluorescence (13-fold), whereas addition to duplex oligodeoxynucleotides containing 2-aminopurine at the 3'- or 5'-neighbouring position leads only to small fluorescence increases. These results give the first experimental evidence that the adenine-specific DNA methyltransferase M. Taq I also flips its target base.

High affinity binding of MEF-2C correlates with DNA bending

To regulate lineage-specific gene expression in many cell types, members of the myocyte enhancer factor-2 (MEF-2) family of transcription factors cooperate with basic helix-loop-helix (bHLH) proteins, which show only limited intrinsic DNA binding specificity. We investigated the DNA binding properties of MEF-2C in vitro and show that the inherent bendability of the MEF site is one of the principal structural characteristics recognized by MEF-2C. Measurements of the apparent dissociation constants of MEF-2C complexes with several DNA sequences revealed that MEF-2C bound with high affinity to DNA sequences containing a MEF site. Mutations in the MEF site which did not affect the bendability of the DNA changed the free energy of binding only marginally. However, reducing the intrinsic bendability of the DNA binding site through an AA-->GC substitution increased the half-maximal binding concentration of MEF-2C by almost one order of magnitude. Electrophoretic mobility shift assays revealed markedly reduced MEF-2C binding to DNA containing 2,6-diaminopurine. On binding to MEF-2C the maximum ellipticity at 275 nm in the CD spectrum of DNA containing a MEF site was red shifted by 4 nm and its intensity reduced significantly, while a slight blue shift of <1 nm was observed for a mutant DNA sequence with reduced bendability (AA-->GC). Bending analysis by circular permutation assay revealed that the DNA in the cognate complex was bent by 49 degrees , while the DNA in the complex with the mutant oligonucleotide was largely unbent.

Substrate DNA and cofactor regulate the activities of a multi-functional restriction-modification enzyme, BcgI

The BcgI restriction-modification system consists of two subunits, A and B. It is a bifunctional protein complex which can cleave or methylate DNA. The regulation of these competing activities is determined by the DNA substrates and cofactors. BcgI is an active endonuclease and a poor methyltransferase on unmodified DNA substrates. In contrast, BcgI is an active methyltransferase and an inactive endonuclease on hemimethylated DNA substrates. The cleavage and methylation reactions share cofactors. While BcgI requires Mg2+and S -adenosyl methionine (AdoMet) for DNA cleavage, its methylation reaction requires only AdoMet and yet is significantly stimulated by Mg2+. Site-directed mutagenesis was carried out to investigate the relationship between AdoMet binding and BcgI DNA cleavage/methylation activities. Most substitutions of conserved residues forming the AdoMet binding pocket in the A subunit abolished both methylation and cleavage activities, indicating that AdoMet binding is an early common step required for both cleavage and methylation. However, one mutation (Y439A) abolished only the methylation activity, not the DNA cleavage activity. This mutant protein was purified and its methylation, cleavage and AdoMet binding activities were tested in vitro . BcgI-Y439A had no detectable methylation activity, but it retained 40% of the AdoMet binding and DNA cleavage activities.

Homing endonucleases: keeping the house in order

Homing endonucleases are rare-cutting enzymes encoded by introns and inteins. They have striking structural and functional properties that distinguish them from restriction enzymes. Nomenclature conventions analogous to those for restriction enzymes have been developed for the homing endonucleases. Recent progress in understanding the structure and function of the four families of homing enzymes is reviewed. Of particular interest are the first reported structures of homing endonucleases of the LAGLIDADG family. The exploitation of the homing enzymes in genome analysis and recombination research is also summarized. Finally, the evolution of homing endonucleases is considered, both at the structure-function level and in terms of their persistence in widely divergent biological systems.

The specificity of sty SKI, a type I restriction enzyme, implies a structure with rotational symmetry

The type I restriction and modification (R-M) enzyme from Salmonella enterica serovar kaduna ( Sty SKI) recognises the DNA sequence 5'-CGAT(N)7GTTA, an unusual target for a type I R-M system in that it comprises two tetranucleotide components. The amino target recognition domain (TRD) of Sty SKI recognises 5'-CGAT and shows 36% amino acid identity with the carboxy TRD of Eco R124I which recognises the complementary, but degenerate, sequence 5'-RTCG. Current models predict that the amino and carboxy TRDs of the specificity subunit are in inverted orientations within a structure with 2-fold rotational symmetry. The complementary target sequences recognised by the amino TRD of Sty SKI and the carboxy TRD of Eco R124I are consistent with the predicted inverted positions of the TRDs. Amino TRDs of similar amino acid sequence have been shown to recognise the same nucleotide sequence. The similarity reported here, the first example of one between amino and carboxy TRDs, while consistent with a conserved mechanism of target recognition, offers additional flexibility in the evolution of sequence specificity by increasing the potential diversity of DNA targets for a given number of TRDs. Sty SKI identifies the first member of the IB family in Salmonella species.

The RuvC protein dimer resolves Holliday junctions by a dual incision mechanism that involves base-specific contacts

The Escherichia coli RuvC protein resolves DNA intermediates produced during genetic recombination. In vitro, RuvC binds specifically to Holliday junctions and resolves them by the introduction of nicks into two strands of like polarity. In contrast to junction recognition, which occurs without regard for DNA sequence, resolution occurs preferentially at sequences that exhibit the consensus 5'-(A/T)TT/(G/C)-3' (where / indicates the site of incision). Synthetic Holliday junctions containing modified cleavage sequences have been used to investigate the mechanism of cleavage. The results indicate that specific DNA sequences are required for the correct docking of DNA into the two active sites of the RuvC dimer. In addition, using chemically modified oligonucleotides to introduce a hydrolysis-resistant 3'-S-phosphorothiolate linkage at the cleavage site, it was found that, as long as the sequence requirements are fulfilled, the two incisions could be uncoupled from each other. These results indicate that RuvC protein resolves Holliday junctions by a mechanism similar to that exhibited by certain restriction enzymes.

Binding, bending and cleavage of DNA substrates by the homing endonuclease Pl-SceI

To characterize the interaction between the homing endonuclease PI-SceI and DNA, we prepared different DNA substrates containing the natural recognition sequence or parts thereof. Depending on the nature of the substrates, efficient cleavage is observed with a DNA containing approximatel 30 bp of the natural recognition sequence using supercoiled plasmids, approximately 40-50 bp using linearized plasmids and > 50 bp using synthetic double-stranded oligodeoxynucleotides. Cleavage of supercoiled plasmids occurs without accumulation of the nicked intermediate. In the presence of Mn2+, DNA cleavage by PI-SceI is more efficient than with Mg2+ and already occurs with substrates containing a shorter part of the recognition sequence. The requirements for strong binding are less stringent: a 35 bp oligodeoxynucleotide which is not cleaved is bound as firmly as other longer oligodeoxynucleotides. PI-SceI binds with high affinity to one of its cleavage products, a finding which may explain why PI-SceI hardly shows enzymatic turnover in vitro. Upon binding, two complexes are formed, which differ in the degree of bending (45 degrees versus 75 degrees). According to a phasing analysis bending is directed into the major groove. Strong binding, not, however, cleavage is also observed with the genetically engineered enzymatically inactive variant comprising amino acids 1-277. Models for binding and cleavage of DNA by PI-SceI are discussed based on these results.

Cloning and sequence comparison of AvaI and BsoBI restriction-modification systems

AvaI and BsoBI restriction endonucleases are isoschizomers which recognize the symmetric sequence 5'CYCGRG3' and cleave between the first C and second Y to generate a four-base 5' extension. The AvaI restriction endonuclease gene (avaIR) and methylase gene (avaIM) were cloned into Escherichia coli by the methylase selection method. The BsoBI restriction endonuclease gene (bsoBIR) and part of the BsoBI methylase gene (bsoBIM) were cloned by the "endo-blue" method (SOS induction assay), and the remainder of bsoBIM was cloned by inverse PCR. The nucleotide sequences of the two restriction-modification (RM) systems were determined. Comparisons of the predicted amino acid sequences indicated that AvaI and BsoBI endonucleases share 55% identity, whereas the two methylases share 41% identity. Although the two systems show similarity in protein sequence, their gene organization differs. The avaIM gene precedes avaIR in the AvaI RM system, while the bsoBI R gene is located upstream of bsoBI M in the BsoBI RM system. Both AvaI and BsoBI methylases contain motifs conserved among the N4 cytosine methylases.

Linear diffusion of the restriction endonuclease EcoRV on DNA is essential for the in vivo function of the enzyme

Linear diffusion along DNA is a mechanism of enhancing the association rates of proteins to their specific recognition sites on DNA. It has been demonstrated for several proteins in vitro, but to date in no case in vivo. Here we show that the restriction endonuclease EcoRV slides along the DNA, scanning approximately 1000 bp in one binding event. This process is critically dependent on contacts between amino acid residues of the protein and the backbone of the DNA. The disruption of single hydrogen bonds and, in particular, the alteration of electrostatic interactions between amino acid side chains of the protein and phosphate groups of the DNA interfere with or abolish effective sliding. The efficiency of linear diffusion is dependent on salt concentration, having a maximum at 50 mM NaCl. These results suggest that a nonspecific and mobile binding mode capable of linear diffusion is dependent on a subtle balance of forces governing the interaction of the enzyme and the DNA. A strong correlation between the ability of EcoRV mutants to slide along the DNA in vitro and to protect Escherichia coli cells from phage infection demonstrates that linear diffusion occurs in vivo and is essential for effective phage restriction.

Sequence-specific recognition of cytosine C5 and adenine N6 DNA methyltransferases requires different deformations of DNA

DNA methyltransferases modify specific cytosines and adenines within 2-6 bp recognition sequences. We used scanning force microscopy and gel shift analysis to show that M.HhaI, a cytosine C-5 DNA methyltransferase, causes only a 2 degree bend upon binding its recognition site. Our results are consistent with prior crystallographic analysis showing that the enzyme stabilizes an extrahelical base while leaving the DNA duplex otherwise unperturbed. In contrast, similar analysis of M.EcoRI, an adenine N6 DNA methyltransferase, shows an average bend angle of approximately 52 degrees. This distortion of DNA conformation by M.EcoRI is shown to be important for sequence-specific binding.

Introduction of asymmetry in the naturally symmetric restriction endonuclease EcoRV to investigate intersubunit communication in the homodimeric protein

Type II restriction endonucleases are dimers of two identical subunits that together form one binding site for the double-stranded DNA substrate. Cleavage within the palindromic recognition site occurs in the two strands of the duplex in a concerted manner, due to the action of two catalytic centers, one per subunit. To investigate how the two identical subunits of the restriction endonuclease EcoRV cooperate in binding and cleaving their substrate, heterodimeric versions of EcoRV with different amino acid substitutions in the two subunits were constructed. For this purpose, the ecorV gene was fused to the coding region for the glutathione-binding domain of the glutathione S-transferase and a His6-tag, respectively. Upon cotransformation of Escherichia coli cells with both gene fusions stable homo- and heterodimers of the EcoRV variants are produced, which can be separated and purified to homogeneity by affinity chromatography over Ni-nitrilotriacetic acid and glutathione columns. A steady-state kinetic analysis shows that the activity of a heterodimeric variant with one inactive catalytic center is decreased by 2-fold, demonstrating that the two catalytic centers operate independently from each other. In contrast, heterodimeric variants with a defect in one DNA-binding site have a 30- to 50-fold lower activity, indicating that the two subunits of EcoRV cooperate in the recognition of the palindromic DNA sequence. By combining a subunit with an inactive catalytic center with a subunit with a defect in the DNA-binding site, EcoRV heterodimers were produced that only nick DNA specifically within the EcoRV recognition sequence.

Multiple roles for divalent metal ions in DNA transposition: distinct stages of Tn10 transposition have different Mg2+ requirements

Tn10 transposition takes place by a non-replicative mechanism in which the transposon is excised from donor DNA and integrated into a target site. Mg2+ is an essential cofactor in this reaction. We have examined the Mg2+ requirements at various steps in Tn10 transposition. Results presented here demonstrate that Tn10 excision can occur efficiently at a 16-fold lower Mg2+ concentration than strand transfer and that, at Mg2+ concentrations in the range of 60-fold below the wildt-ype optimum, double strand cleavage events at the two transposon ends are completely uncoupled. These experiments identify specific breakpoints in Tn10 transposition which are sensitive to Mg2+ concentration. Whereas the uncoupling of double strand cleavage events at the two transposon ends most likely reflects the inability of two separate IS10 transposase monomers in the synaptic complex to bind Mg2+, the uncoupling of transposon excision from strand transfer is expected to reflect either a conformational change in the active site or the existence of an Mg2+ binding site which functions specifically in target interactions. We also show that Mn2+ relaxes target specificity in Tn10 transposition and suppresses a class of mutants which are blocked specifically for integration. These observations can be explained by a model in which sequence-specific target site binding is tightly coupled to a conformational change in the synaptic complex which is required for catalysis of strand transfer.

Crystal structure of a human TATA box-binding protein/TATA element complex

The TATA box-binding protein (TBP) is required by all three eukaryotic RNA polymerases for correct initiation of transcription of ribosomal, messenger, small nuclear, and transfer RNAs. The cocrystal structure of the C-terminal/core region of human TBP complexed with the TATA element of the adenovirus major late promoter has been determined at 1.9 angstroms resolution. Structural and functional analyses of the protein-DNA complex are presented, with a detailed comparison to our 1.9-angstroms resolution structure of Arabidopsis thaliana TBP2 bound to the same TATA box.

Defining the enzyme binding domain of a ribonuclease III processing signal. Ethylation interference and hydroxyl radical footprinting using catalytically inactive RNase III mutants

Ethylation interference and hydroxyl radical footprinting were used to identify substrate ribose-phosphate backbone sites that interact with the Escherichia coli RNA processing enzyme, ribonuclease III. Two RNase III mutants were employed, which bind substrate in vitro similarly as wild-type enzyme, but lack detectable phosphodiesterase activity. Specifically, altering glutamic acid at position 117 to lysine or alanine uncouples substrate binding from cleavage. The two substrates examined are based on the bacteriophage T7 R1.1 RNase III processing signal. One substrate, R1.1 RNA, undergoes accurate single cleavage at the canonical site, while a close variant, R1.1[WC-L] RNA, undergoes coordinate double cleavage. The interference and footprinting patterns for each substrate (i) overlap, (ii) exhibit symmetry and (iii) extend approximately one helical turn in each direction from the RNase III cleavage sites. Divalent metal ions (Mg2+, Ca2+) significantly enhance substrate binding, and confer stronger protection from hydroxyl radicals, but do not significantly affect the interference pattern. The footprinting and interference patterns indicate that (i) RNase III contacts the sugar-phosphate backbone; (ii) the RNase III-substrate interaction spans two turns of the A-form helix; and (iii) divalent metal ion does not play an essential role in binding specificity. These results rationalize the conserved two-turn helix motif seen in most RNase III processing signals, and which is necessary for optimal processing reactivity. In addition, the specific differences in the footprint and interference patterns of the two substrates suggest why RNase III catalyzes the coordinate double cleavage of R1.1[WC-L] RNA, and dsRNA in general, while catalyzing only single cleavage of R1.1 RNA and related substrates in which the scissle bond is within an asymmetric internal loop.

The crystal structure analysis of d(CGCGAASSCGCG)2, a synthetic DNA dodecamer duplex containing four 4'-thio-2'-deoxythymidine nucleotides

The crystal structure refinement of the synthetic dodecamer d(CGCGAASSCGCG), where S = 4'-thio-2'-deoxythymidine, has converged at R=0.201 for 2605 reflections with F > 2sigma(F) in the resolution range 8.0-2.4 A for a model consisting of the dodecamer duplex and 66 water molecules. A comparison of its structure with that of the native dodecamer d(CGCGAATTCGCG) has revealed that the major differences between the two structures is a change in the conformation of the sugar-phosphate backbone in the regions at and adjacent to the positions of the modified nucleosides. Examination of the fine structural parameters for each of the structures reveals that the thiosugars adopt a C3'-exo conformation in d(CGCGAASSCGCG), rather than the approximate C1'-exo conformation found for the analogous sugars in the structure of d(CGCGAATTCGCG). The observed differences in structure between the two duplexes may help to explain the enhanced resistance to nuclease digestion of synthetic oligonucleotides containing 4'-thio-2'-deoxynucleotides.

Horizontal gene transfer contributes to the wide distribution and evolution of type II restriction-modification systems

Restriction modification (RM) systems serve to protect bacteria against bacteriophages. They comprise a restriction endonuclease activity that specifically cleaves DNA and a corresponding methyltransferase activity that specifically methylates the DNA, thereby protecting it from cleavage. Such systems are very common in bacteria. To find out whether the widespread distribution of RM systems is due to horizontal gene transfer, we have compared the codon usages of 29 type II RM systems with the average codon usage of their respective bacterial hosts. Pronounced deviations in codon usage were found in six cases: EcoRI, EcoRV, KpnI, SinI, SmaI, and TthHB81. They are interpreted as evidence for horizontal gene transfer in these cases. As the methodology is expected to detect only one-fourth to one-third of all horizontal gene transfer events, this result implies that horizontal gene transfer had a considerable influence on the distribution and evolution of RM systems. In all of these six cases the codon usage deviations of the restriction enzyme genes are much more pronounced than those of the methyltransferase genes. This result suggests that in these cases horizontal gene transfer had occurred sequentially with the gene for the methyltransferase being first acquired by the cell. This can be explained by the fact that an active restriction endonuclease is highly toxic in cells whose DNA is not protected from cleavage by a corresponding methyltransferase.

DNA determinants in sequence-specific recognition by XmaI endonuclease

The XmaI endonuclease recognizes and cleaves the sequence C decreases CCGGG. Magnesium is required for catalysis, however, the enzyme forms stable, specific complexes with DNA in the absence of magnesium. An association constant of 1.2 x 10(9)/M was estimated for the affinity of the enzyme for a specific 195 bp fragment. Competition assays revealed that the site-specific association constant represented an approximately 10(4)-fold increase in affinity over that for non-cognate sites. Missing nucleoside analyses suggested an interaction of the enzyme with each of the cytosines and guanines within the recognition site. Recognition of each of the guanines was also indicated by dimethylsulfate interference footprinting assays. The phosphates 5' to the guanines within the recognition site appeared to be the major sites of interaction of XmaI with the sugar-phosphate backbone. No significant interaction of the protein was observed with phosphates flanking the recognition sequence. Comparison of the footprinting patterns of XmaI with those of the neoschizomer SmaI (CCC decreases GGG) revealed that the two enzymes utilize the same DNA determinants in their specific interaction with the CCCGGG recognition site.

Analysis of local helix bending in crystal structures of DNA oligonucleotides and DNA-protein complexes

Sequence-dependent bending of the helical axes in 112 oligonucleotide duplex crystal structures resident in the Nucleic Acid Database have been analyzed and compared with the use of bending dials, a computer graphics tool. Our analysis includes structures of both A and B forms of DNA and considers both uncomplexed forms of the double helix as well as those bound to drugs and proteins. The patterns in bending preferences in the crystal structures are analyzed by base pair steps, and emerging trends are noted. Analysis of the 66 B-form structures in the Nucleic Acid Database indicates that uniform trends within all pyrimidine-purine and purine-pyrimidine steps are not necessarily observed but are found particularly at CG and GC steps of dodecamers. The results support the idea that AA steps are relatively straight and that larger roll bends occur at or near the junctions of these A-tracts with their flanking sequences. The data on 16 available crystal structures of protein-DNA complexes indicate that the majority of the DNA bends induced via protein binding are sharp localized kinks. The analysis of the 30 available A-form DNA structures indicates that these structures are also bent and show a definitive preference for bending into the deep major groove over the shallow minor groove.

Tyrosine 27 of the specificity polypeptide of EcoKI can be UV crosslinked to a bromodeoxyuridine-substituted DNA target sequence

The specificity (S) subunit of the restriction enzyme EcoKI imparts specificity for the sequence AAC(N6)GTGC. Substitution of thymine with bromodeoxyuridine in a 25 bp DNA duplex containing this sequence stimulated UV light-induced covalent crosslinking to the S subunit. Crosslinking occurred only at the residue complementary to the first adenine in the AAC sequence, demonstrating a close contact between the major groove at this sequence and the S subunit. Peptide sequencing of a proteolytically-digested, crosslinked complex identified tyrosine 27 in the S subunit as the site of crosslinking. This is consistent with the role of the N-terminal domain of the S subunit in recognizing the AAC sequence. Tyrosine 27 is conserved in the S subunits of the three type I enzymes that share the sequence AA in the trinucleotide component of their target sequence. This suggests that tyrosine 27 may make a similar DNA contact in these other enzymes.

Heterogeneity in molecular recognition by restriction endonucleases: osmotic and hydrostatic pressure effects on BamHI, Pvu II, and EcoRV specificity

The cleavage specificity of the Pvu II and BamHI restriction endonucleases is found to be dramatically reduced at elevated osmotic pressure. Relaxation in specificity of these otherwise highly accurate and specific enzymes, previously termed "star activity," is uniquely correlated with osmotic pressure between 0 and 100 atmospheres. No other colligative solvent property exhibits a uniform correlation with star activity for all of the compounds tested. Application of hydrostatic pressure counteracts the effects of osmotic pressure and restores the natural selectivity of the enzymes for their canonical recognition sequences. These results indicate that water solvation plays an important role in the site-specific recognition of DNA by many restriction enzymes. Osmotic pressure did not induce an analogous effect on the specificity of the EcoRV endonuclease, implying that selective hydration effects do not participate in DNA recognition in this system. Hydrostatic pressure was found to have little effect on the star activity induced by changes in ionic strength, pH, or divalent cation, suggesting that distinct mechanisms may exist for these observed alterations in specificity. Recent evidence has indicated that BamHI and EcoRI share similar structural motifs, while Pvu II and EcoRV belong to a different structural family. Evidently, the use of hydration water to assist in site-specific recognition is a motif neither limited to nor defined by structural families.

Direct selection of binding proficient/catalytic deficient variants of BamHI endonuclease

Variants of BamHI endonuclease in which the glutamate 113 residue has been changed to lysine or the aspartate 94 to asparagine were shown to behave as repressor molecules in vivo. This was demonstrated by placing a BamHI recognition sequence, GGATCC, positioned as an operator sequence in an antisense promoter for the aadA gene (spectinomycin resistance). Repression of this promoter relieved the inhibition of expression of spectinomycin resistance. This system was then used to select new binding proficient/cleavage deficient BamHI variants. The BamHI endonuclease gene was mutagenized either by exposure to hydroxylamine or by PCR. The mutagenized DNA was reintroduced into E. coli carrying the aadA gene construct, and transformants that conferred spectinomycin resistance were selected. Twenty Spr transformants were sequenced. Thirteen of these were newly isolated variants of the previously identified D94 and E113 residues which are known to be involved in catalysis. The remaining seven variants were all located at residue 111 and the glutamate 111 residue was shown to be involved with catalysis.

Interaction of the intron-encoded mobility endonuclease I-PpoI with its target site

Endonucleases encoded by mobile group I introns are highly specific DNases that induce a double-strand break near the site to which the intron moves. I-PpoI from the acellular slime mold Physarum polycephalum mediates the mobility of intron 3 (Pp LSU 3) in the extrachromosomal nuclear ribosomal DNA of this organism. We showed previously that cleavage by I-PpoI creates a four-base staggered cut near the point of intron insertion. We have now characterized several further properties of the endonuclease. As determined by deletion analysis, the minimal target site recognized by I-PopI was a sequence of 13 to 15 bp spanning the cleavage site. The purified protein behaved as a globular dimer in sedimentation and gel filtration. In gel mobility shift assays in the presence of EDTA, I-PpoI formed a stable and specific complex with DNA, dissociating with a half-life of 45 min. By footprinting and interference assays with methidiumpropyl-EDTA-iron(II), I-PpoI contacted a 22- to 24-bp stretch of DNA. The endonuclease protected most of the purines found in both the major and minor grooves of the DNA helix from modification by dimethyl sulfate (DMS). However, the reactivity to DMS was enhanced at some purines, suggesting that binding leads to a conformational change in the DNA. The pattern of DMS protection differed fundamentally in the two partially symmetrical halves of the recognition sequence.

Interaction of the intron-encoded mobility endonuclease I-PpoI with its target site

Endonucleases encoded by mobile group I introns are highly specific DNases that induce a double-strand break near the site to which the intron moves. I-PpoI from the acellular slime mold Physarum polycephalum mediates the mobility of intron 3 (Pp LSU 3) in the extrachromosomal nuclear ribosomal DNA of this organism. We showed previously that cleavage by I-PpoI creates a four-base staggered cut near the point of intron insertion. We have now characterized several further properties of the endonuclease. As determined by deletion analysis, the minimal target site recognized by I-PopI was a sequence of 13 to 15 bp spanning the cleavage site. The purified protein behaved as a globular dimer in sedimentation and gel filtration. In gel mobility shift assays in the presence of EDTA, I-PpoI formed a stable and specific complex with DNA, dissociating with a half-life of 45 min. By footprinting and interference assays with methidiumpropyl-EDTA-iron(II), I-PpoI contacted a 22- to 24-bp stretch of DNA. The endonuclease protected most of the purines found in both the major and minor grooves of the DNA helix from modification by dimethyl sulfate (DMS). However, the reactivity to DMS was enhanced at some purines, suggesting that binding leads to a conformational change in the DNA. The pattern of DMS protection differed fundamentally in the two partially symmetrical halves of the recognition sequence.

Substrate-assisted catalysis in the cleavage of DNA by the EcoRI and EcoRV restriction enzymes

The crystal structure analyses of the EcoRI-DNA and EcoRV-DNA complexes do not provide clear suggestions as to which amino acid residues are responsible for the activation of water to carry out the DNA cleavage. Based on molecular modeling, we have proposed recently that the attacking water molecule is activated by the negatively charged pro-Rp phosphoryl oxygen of the phosphate group 3' to the scissile phosphodiester bond. We now present experimental evidence to support this proposal. (i) Oligodeoxynucleotide substrates lacking this phosphate group in one strand are cleaved only in the other strand. (ii) Oligodeoxynucleotide substrates carrying an H-phosphonate substitution at this position in both strands and, therefore, lacking a negatively charged oxygen at this position are cleaved at least four orders of magnitude more slowly than the unmodified substrate. These results are supported by other modification studies: oligodeoxynucleotide substrates with a phosphorothioate substitution at this position in both strands are cleaved only if the negatively charged sulfur is in the RP configuration as shown for EcoRI [Koziolkiewicz, M. & Stec, W.J. (1992) Biochemistry 31, 9460-9466] and EcoRV (B. A. Connolly, personal communication). As the phosphate residue 3' to the scissile phosphodiester bond is not needed for strong DNA binding by both enzymes, these findings strongly suggest that this phosphate group plays an active role during catalysis. This proposal, furthermore, gives a straightforward explanation of why in the EcoRI-DNA and EcoRV-DNA complexes the DNA is distorted differently, but in each case the 3' phosphate group closely approaches the phosphate group that is attacked. Finally, an alternative mechanism for DNA cleavage involving two metal ions is unlikely in the light of our finding that both EcoRI and EcoRV need only one Mg2+ per active site for cleavage.

Synthesis and properties of oligodeoxynucleotides containing the analogue 2'-deoxy-4'-thiothymidine

The 2'-deoxythymidine analogue 2'-deoxy-4'-thiothymidine has been incorporated, using standard methodology, into a series of dodecadeoxynucleotides containing the EcoRV restriction endonuclease recognition site (GATATC). The stability of these oligodeoxynucleotides and their ability to act as substrates for the restriction endonuclease and associated methylase have been compared with a normal unmodified oligodeoxynucleotide. No problems were encountered in the synthesis despite the presence of a potentially oxidisable sulfur atom in the sugar ring. The analogue had very little effect on the melting temperature of the self-complementary oligoeoxynucleotides so synthesised and all had a CD spectrum compatible with a B-DNA structure. The oligodeoxynucleotide containing one analogue in each strand within the recognition site, adjacent to the bond to be cleaved (i.e. GAXATC, where X is 2'-deoxy-4'-thiothymidine), was neither a substrate for the endonuclease nor was recognized by the associated methylase. When still within the recognition hexanucleotide but two further residues removed from the site of cleavage (i.e. GATAXC), the oligodeoxynucleotide was a poor substrate for both the endonuclease and methylase. Binding of the oligodeoxynucleotide to the endonuclease was unaffected but the kcat value was only 0.03% of the value obtained for the parent oligodeoxynucleotide. These results show that the incorporation of 2'-deoxy-4'-thionucleosides into synthetic oligodeoxynucleotides may shed light on subtle interactions between proteins and their normal substrates and may also show why 2'-deoxy-4'-thiothymidine itself is so toxic in cell culture.