The modular character of a DNA junction-resolving enzyme: a zinc-binding motif in bacteriophage T4 endonuclease VII

Exploring the Catalytic Mechanism of Cas9 Using Information Inferred from Endonuclease VII

Elucidating the nature of the gene editing mechanism of CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) is an important task in view of the role of this breakthrough to the advancement of human medicine. In particular, it is crucial to understand the catalytic mechanism of Cas9 (one of the CRISPR associated proteins) and its role in confirming accurate editing. Thus, we focus in this work on an attempt to analyze the catalytic mechanism of Cas9. Considering the absence of detailed structural information on the active form of Cas9, we use an empirical valence bond (EVB) which is calibrated on the closely related mechanism of T4 endonuclease VII. The calibrated EVB is then used in studying the reaction of Cas9, while trying several structural models. It is found that the catalytic activation requires a large conformational change, where K848 or other positively charged group moves from a relatively large distance toward the scissile phosphate. This conformational change leads to the change in position of the Mg²⁺ ion and to a major reduction in the activation barrier for the catalytic reaction. Our finding provides an important clue on the nature of the catalytic activation of CAS9 and thus should help in elucidating a key aspect of the gene editing process. For example, the approach used here should be effective in exploring the nature of off target activation and its relationship to the energetics of the unwinding process. This strategy may offer ways to improve the selectivity of Cas9.

F-CphI represents a new homing endonuclease family using the Endo VII catalytic motif

Background

There are six known families of homing endonucleases, LAGLIDADG, GIY-YIG, HNH, His-Cys box, PD-(D/E)-XK, and EDxHD, which are characterized by their conserved residues. Previously, we discovered a novel homing endonuclease F-CphI encoded by ORF177 of cyanophage S-PM2. F-CphI does not resemble any characterized homing endonucleases. Instead, the C-terminus of F-CphI aligns well with the N-terminal catalytic domain of a Holliday junction DNA resolvase, phage T4 endonuclease VII (Endo VII).

Results

A PSI-BLAST search resulted in a total of 313 Endo VII motif–containing sequences in sequenced genomes. Multiple sequence alignment showed that the catalytically important residues of T4 Endo VII were all well conserved in these proteins. Our site-directed mutagenesis studies further confirmed that the catalytically important residues of T4 Endo VII were also essential for F-CphI activity, and thus F-CphI might use a similar protein fold as Endo VII for DNA cleavage. A phylogenetic tree of the Endo VII motif–containing sequences showed that putative resolvases grouped into one clade while putative homing endonucleases and restriction endonucleases grouped into another clade.

Conclusions

Based on the unique conserved residues, we proposed that F-CphI represents a new homing endonuclease family, which was named the DHHRN family. Our phylogenetic analysis could be used to predict the functions of many previously unknown proteins.

Electronic supplementary material

The online version of this article (10.1186/s13100-018-0132-5) contains supplementary material, which is available to authorized users.

Mycobacterium tuberculosis RuvX is a Holliday junction resolvase formed by dimerisation of the monomeric YqgF nuclease domain

The Mycobacterium tuberculosis genome possesses homologues of the ruvC and yqgF genes that encode putative Holliday junction (HJ) resolvases. However, their gene expression profiles and enzymatic properties have not been experimentally defined. Here we report that expression of ruvC and yqgF is induced in response to DNA damage. Protein-DNA interaction assays with purified M. tuberculosis RuvC (MtRuvC) and YqgF (MtRuvX) revealed that both associate preferentially with HJ DNA, albeit with differing affinities. Although both MtRuvC and MtRuvX cleaved HJ DNA in vitro, the latter displayed robust HJ resolution activity by symmetrically related, paired incisions. MtRuvX showed a higher binding affinity for the HJ structure over other branched recombination and replication intermediates. An MtRuvX(D28N) mutation, eliminating one of the highly conserved catalytic residues in this class of endonucleases, dramatically reduced its ability to cleave HJ DNA. Furthermore, a unique cysteine (C38) fulfils a crucial role in HJ cleavage, consistent with disulfide-bond mediated dimerization being essential for MtRuvX activity. In contrast, E. coli YqgF is monomeric and exhibits no branched DNA binding or cleavage activity. These results fit with a functional modification of YqgF in M. tuberculosis so that it can act as a dimeric HJ resolvase analogous to that of RuvC.

Elimination of inter-domain interactions increases the cleavage fidelity of the restriction endonuclease DraIII

DraIII is a type IIP restriction endonucleases (REases) that recognizes and creates a double strand break within the gapped palindromic sequence CAC↑NNN↓GTG of double-stranded DNA (↑ indicates nicking on the bottom strand; ↓ indicates nicking on the top strand). However, wild type DraIII shows significant star activity. In this study, it was found that the prominent star site is CAT↑GTT↓GTG, consisting of a star 5′ half (CAT) and a canonical 3′ half (GTG). DraIII nicks the 3′ canonical half site at a faster rate than the 5′ star half site, in contrast to the similar rate with the canonical full site. The crystal structure of the DraIII protein was solved. It indicated, as supported by mutagenesis, that DraIII possesses a ββα-metal HNH active site. The structure revealed extensive intra-molecular interactions between the N-terminal domain and the C-terminal domain containing the HNH active site. Disruptions of these interactions through site-directed mutagenesis drastically increased cleavage fidelity. The understanding of fidelity mechanisms will enable generation of high fidelity REases.

Mutants of phage bIL67 RuvC with enhanced Holliday junction binding selectivity and resolution symmetry

Viral and bacterial Holliday junction resolvases differ in specificity with the former typically being more promiscuous, acting on a variety of branched DNA substrates, while the latter exclusively targets Holliday junctions. We have determined the crystal structure of a RuvC resolvase from bacteriophage bIL67 to help identify features responsible for DNA branch discrimination. Comparisons between phage and bacterial RuvC structures revealed significant differences in the number and position of positively-charged residues in the outer sides of the junction binding cleft. Substitutions were generated in phage RuvC residues implicated in branch recognition and six were found to confer defects in Holliday junction and replication fork cleavage in vivo. Two mutants, R121A and R124A that flank the DNA binding site were purified and exhibited reduced in vitro binding to fork and linear duplex substrates relative to the wild-type, while retaining the ability to bind X junctions. Crucially, these two variants cleaved Holliday junctions with enhanced specificity and symmetry, a feature more akin to cellular RuvC resolvases. Thus, additional positive charges in the phage RuvC binding site apparently stabilize productive interactions with branched structures other than the canonical Holliday junction, a feature advantageous for viral DNA processing but deleterious for their cellular counterparts.

Putative Functional Domains of Human Cytomegalovirus pUL56 Involved in Dimerization and Benzimidazole D-Ribonucleoside Activity

Background

Benzimidazole d-ribonucleosides inhibit DNA packaging during human cytomegalovirus (HCMV) replication. Although they have been shown to target pUL56 and pUL89 (the large and small subunits of the HCMV terminase, respectively) their mechanism of action is not yet fully understood. We aimed here to better understand HCMV DNA maturation and the mechanism of action of benzimidazole derivatives.

Methods

The HCMV pUL56 protein was studied by sequence analysis of the HCMV UL56 gene and herpesvirus counterparts combined with primary structure analysis of the corresponding amino acid sequences.

Results

The UL56 sequence analysis of 45 HCMV strains and counterparts among herpesviruses allowed the identification of 12 conserved regions. Moreover, comparison with the product of gene 49 (gp49) of bacteriophage T4 suggested that the pUL56 zinc finger is localized close to the dimerization site of pUL56, providing a spatial organization of the catalytic site that allows recognition and cleavage of DNA.

Conclusions

This study provides a basis to investigate the mechanism of concatemeric DNA cleavage and a biochemical basis for DNA packaging inhibition by benzimidazole derivatives.

Characterization of the C-terminal DNA-binding/DNA endonuclease region of a group II intron-encoded protein

Group II intron retrohoming occurs by a mechanism in which the intron RNA reverse splices directly into one strand of a double-stranded DNA target site, while the intron-encoded reverse transcriptase uses a C-terminal DNA endonuclease activity to cleave the opposite strand and then uses the cleaved 3' end as a primer for reverse transcription of the inserted intron RNA. Here, we characterized the C-terminal DNA-binding/DNA endonuclease region of the LtrA protein encoded by the Lactococcus lactis Ll.LtrB intron. This C-terminal region consists of an upstream segment that contributes to DNA binding, followed by a DNA endonuclease domain that contains conserved sequence motifs characteristic of H-N-H DNA endonucleases, interspersed with two pairs of conserved cysteine residues. Atomic emission spectroscopy of wild-type and mutant LtrA proteins showed that the DNA endonuclease domain contains a single tightly bound Mg(2+) ion at the H-N-H active site. Although the conserved cysteine residue pairs could potentially bind Zn(2+), the purified LtrA protein is active despite the presence of only sub-stoichiometric amounts of Zn(2+), and the addition of exogenous Zn(2+) inhibits the DNA endonuclease activity. Multiple sequence alignments identified features of the DNA-binding region and DNA endonuclease domain that are conserved in LtrA and related group II intron proteins, and their functional importance was demonstrated by unigenic evolution analysis and biochemical assays of mutant LtrA protein with alterations in key amino acid residues. Notably, deletion of the DNA endonuclease domain or mutations in its conserved sequence motifs strongly inhibit reverse transcriptase activity, as well as bottom-strand cleavage, while retaining other activities of the LtrA protein. A UV-cross-linking assay showed that these DNA endonuclease domain mutations do not block DNA primer binding and thus likely inhibit reverse transcriptase activity either by affecting the positioning of the primer or the conformation of the reverse transcriptase domain.

The junction-resolving enzymes

Junction-resolving enzymes are ubiquitous nucleases that are important for DNA repair and recombination and act on DNA molecules containing branch points, especially four-way junctions. They show a pronounced selectivity for the structure of the DNA substrate but, despite its importance, the structural selectivity is not well understood. This poses an intriguing challenge in molecular recognition on a relatively large scale.

DNA recognition by structure-selective nucleases

The nucleases discussed in this review show little sequence specificity but instead recognize certain structural features of their respective DNA substrates. The level of their structural selectivity ranges from simple discrimination between single- and double-stranded DNA (nucleases P1 and S1), the recognition of helical parameters like groove width and flexibility (DNase I), the recognition of helical distortions caused by abasic sites (exonuclease III, HAP1), to the recognition of specialized structures like flap DNA (5'-nucleases of eukaryotes, phages, and eubacterial DNA polymerases) and four-way junctions (T4 endonuclease VII, RuvC). The discussion is focused on the structural basis of the recognition process. In most cases the available x-ray structures of the nucleases and/or their DNA complexes have revealed the presence of structural motifs explaining the observed structural selectivity.

X-ray structure of T4 endonuclease VII: a DNA junction resolvase with a novel fold and unusual domain-swapped dimer architecture

Phage T4 endonuclease VII (Endo VII), the first enzyme shown to resolve Holliday junctions, recognizes a broad spectrum of DNA substrates ranging from branched DNAs to single base mismatches. We have determined the crystal structures of the Ca2+-bound wild-type and the inactive N62D mutant enzymes at 2.4 and 2.1 A, respectively. The Endo VII monomers form an elongated, highly intertwined molecular dimer exhibiting extreme domain swapping. The major dimerization elements are two pairs of antiparallel helices forming a novel 'four-helix cross' motif. The unique monomer fold, almost completely lacking beta-sheet structure and containing a zinc ion tetrahedrally coordinated to four cysteines, does not resemble any of the known junction-resolving enzymes, including the Escherichia coli RuvC and lambda integrase-type recombinases. The S-shaped dimer has two 'binding bays' separated by approximately 25 A which are lined by positively charged residues and contain near their base residues known to be essential for activity. These include Asp40 and Asn62, which function as ligands for the bound calcium ions. A pronounced bipolar charge distribution suggests that branched DNA substrates bind to the positively charged face with the scissile phosphates located near the divalent cations. A model for the complex with a four-way DNA junction is presented.

Enzymatic methods for mutation scanning

Enzymatic methods for mutation scanning still lack the sensitivity and specificity of the chemical cleavage of mismatch method. However developments in our understanding of the mismatch recognition process should lead to improvements. Several promising candidates exist with potential for more specific and sensitive mutation detection.

Endonuclease VII has two DNA-binding sites each composed from one N- and one C-terminus provided by different subunits of the protein dimer

Endonuclease VII (endo VII) is a Holliday structure-resolving enzyme of bacteriophage T4. Its activity depends on dimerization, DNA binding and hydrolysis of two phosphodiester bonds flanking the Holliday junction. We analysed the DNA-binding activity of truncated monomeric and covalently linked dimeric endo VII proteins. We show that both ends of endo VII are involved in DNA binding. In particular, the C-terminus of one subunit interacts with the N-terminus of the other subunit, constituting one DNA-binding site; the other two termini form the second binding site of the dimer. One binding site is sufficient to bind cruciform DNA. The concerted mechanism involving termini from different subunits ensures that only dimers bind to Holliday structures, thus providing two catalytic centres which introduce two cleavages in opposite strands. This is a precondition for precise resolution of Holliday structures.

Localization and characterization of the dimerization domain of holliday structure resolving endonuclease VII of phage T4

Endonuclease VII (Endo VII) is a Holliday structure resolving enzyme of bacteriophage T4. Its nucleolytic activity depends on subactivities, which in order of execution are: (i) dimerization, (ii) binding to DNA, (iii) and cleavage of DNA. In an effort to assign these subfunctions to the primary sequence of the protein, a series of spontaneous point mutations deficient in DNA cleavage was isolated. Some of these mutations affected the dimerization of Endo VII. Compared with wild-type protein, which dimerizes completely in solution, more than 95% of one of the mutant proteins (W87R) remained in the monomeric state. Only the dimeric fraction of this protein bound to DNA. The dimerization domain of Endo VII was mapped by truncating the gene from both ends and analysing the dimerization ability of the purified peptides by crosslinking with glutaraldehyde. The dimerization domain was thus determined to reside between amino acid residues 55 and 105. Computer analyses predicted two alpha-helices (H2 and H3) in this section of the protein. As demonstrated by heterodimer formation, two copies of helix H3, but only one copy of helix H2, are required for dimerization. Helical wheel analyses revealed that both helices expose a hydrophobic face along their axes, suggesting that hydrophobic interaction between helices H3 mediate formation of Endo VII dimers, while helices H2 stabilize them.

Structural recognition and distortion by the DNA junction-resolving enzyme RusA

RusA is a relatively small DNA junction-resolving enzyme of lambdoid phage-origin. Many of the physical characteristics of this enzyme are similar to those of junction-resolving enzymes of different origins. RusA binds to DNA junctions as a dimer, with a dissociation constant of 2 to 7 nM. RusA also exists in dimeric form in free solution, with a half time for subunit exchange of 4.2 minutes. We find that RusA can cleave both fixed junctions and those that can undergo a number of steps of branch migration, and confirm that the enzyme exhibits a strong preference for cleavage 5' to a CpC sequence. We have isolated a mutant protein, RusA D70N, that is completely inactive in cleavage while binding normally to DNA junctions, suggesting a role for aspartate 70 in the cleavage reaction. Constraining the conformation of the junction by means of tethering the helical ends leads to a marked reduction in cleavage rate by RusA, suggesting that the structure must be altered for cleavage. Using comparative gel electrophoresis we find that the global structure of the DNA junction is altered on RusA binding, into a structure that is different from any that is formed by the free junction. Moreover, the structure of the complex is the same irrespective of the presence or absence of magnesium ions. Thus, like all the junction-resolving enzymes, RusA both recognises and distorts the structure of DNA junctions.

Epitope mapping of T4 endonuclease VII with monoclonal antibodies reveals importance of both ends of the protein for target binding

Endonuclease VII (endo VII) of bacteriophage T4 is a Holliday-structure resolving enzyme that can also recognize many other defects in DNA via an altered secondary structure. The protein has a molecular mass of 18 kDa and exists as a dimer in solution. Here we report the production and characterization of monoclonal antibodies (mAbs) directed against the highly purified enzyme. From one fusion 15 hybrid cell lines producing mAbs with high affinity for endo VII could be established. The mAbs were used for epitope mapping of the protein by using N-terminal, C-terminal and internal peptides of endo VII as antigens in enzyme-linked immunoabsorbant assays. Three classes of mAbs were distinguished as follows: (1) the predominant class with 13 mAbs recognized a C-terminal epitope located between amino acid residues 115 and 145; (2) a second class, represented by one mAb, recognized an epitope located at the N terminus between amino acid residues 16 and 65; (3) a third class, represented by one mAb, recognized an epitope built from nearly the entire native protein including amino acid residues from the C and N terminus of endo VII. The latter finding suggests close proximity of the two ends, which are provided apparently by the same monomer, since the mAb from class III does also react with a mutant protein deficient in dimerization. Internal sequences of endo VII between amino acid residues 78 and 145 did not react with any of the mAbs.

A new Holliday junction resolving enzyme from Schizosaccharomyces pombe that is homologous to CCE1 from Saccharomyces cerevisiae

The resolution of Holliday junctions is a critical stage in recombination. We describe the identification and initial biochemical characterisation of a new Holliday junction resolvase from Schizosaccharomyces pombe. Resolvase activity was initially detected in partially purified cell-free extracts of S. pombe. Resolution of X-junction DNA occurred by the introduction of symmetrical cuts in strands of the same polarity. All cuts occurred 3' of thymine nucleotides with a possible preference for cleavage one nucleotide 3' from the point of strand crossover. During the course of these studies, a potential S. pombe homologue of the Saccharomyces cerevisiae Cruciform Cutting Endonuclease I was identified in the database (SpCCE1). The gene was cloned by PCR, overexpressed in Escherichia coli and its product purified as a His-tagged fusion protein. Purified SpCCE1 binds to X-junctions in a structure-specific manner and resolves them to nicked linear duplex products that are repairable by DNA ligase. SpCCE1 cuts X-junctions in precisely the same way as the resolvase activity from partially purified extracts of S. pombe, indicating that they are probably the same. Finally, we show that SpCCE1 can function as a Holliday junction resolvase in vivo by its ability to complement a resolvase-deficient strain of E. coli.

Nucleic acid structure and recognition

We review the global structures adopted by branched nucleic acids, including three- and four-way helical junctions in DNA and RNA. We find that some general folding principles emerge. First, all the structures exhibit a tendency to undergo pairwise coaxial helical stacking when permitted by the local stereochemistry of strand exchange. Second, metal ions generally play an important role in facilitating folding of branched nucleic acids. These principles can be applied to functionally important branched nucleic acids, such as the Holliday DNA junction of genetic recombination, and the hammerhead ribozyme in RNA.

Recognition and manipulation of branched DNA structure by junction-resolving enzymes

The junction-resolving enzymes are a class of nucleases that introduce paired cleavages into four-way DNA junctions. They are important in DNA recombination and repair, and are found throughout nature, from eubacteria and their bacteriophages through to higher eukaryotes and their viruses. These enzymes exhibit structure-selective binding to DNA junctions; although cleavage may be more or less sequence-dependent, binding affinity is purely related to the branched structure of the DNA. Binding and cleavage events can be separated for a number of the enzymes by mutagenesis, and mutant proteins that are defective in cleavage while retaining normal junction-selective binding have been isolated. Critical acidic residues have been identified in several resolving enzymes, suggesting a role in the coordination of metal ions that probably deliver the hydrolytic water molecule. The resolving enzymes all bind to junctions in dimeric form, and the subunits introduce independent cleavages within the lifetime of the enzyme-junction complex to ensure resolution of the four-way junction. In addition to recognising the structure of the junction, recent data from four different junction-resolving enzymes indicate that they also manipulate the global structure. In some cases this results in severe distortion of the folded structure of the junction. Understanding the recognition and manipulation of DNA structure by these enzymes is a fascinating challenge in molecular recognition.

Identification of amino acids of endonuclease VII essential for binding and cleavage of cruciform DNA

Endonuclease VII is a Holliday-structure-resolving enzyme of bacteriophage T4. The active protein is a homodimer with 157 amino acids/monomer. An amber mutation (amE727 in codon 151) inactivates the nuclease completely, indicating the importance of the seven C-terminal amino acids for nucleolytic activity. The influence of these amino acids on cruciform-DNA binding and cleavage was investigated through functional analysis of C-terminal-truncated proteins derived from deletion constructs. It was found that the three C-terminal amino acids are not necessary for binding and cleavage. A transition from active to inactive protein occurs gradually with truncations of the next four amino acids. Reduction of DNA-binding ability, as measured by electrophoretic mobility shift assays, was determined to be the primary defect in the cleavage-deficient proteins. This was further concluded by the finding that EVII-(1-150)-peptide(amber), a protein with fairly low affinity to cruciform DNA, contributes cleavage activity to reactions of wild-type EVII with cruciform DNA. [Asp62]EVII-(1-156)-peptide lacking one C-terminal amino acid, contains a point mutation in codon 62 that eliminates the nucleolytic activity of the protein while retaining its DNA-binding proficiency. By mixing binding-deficient and cleavage-deficient mutants in the same assay, cleavage of cruciform DNA resumed. Evidence is presented that complementation occurs by heterodimer formation. Our results show that the zinc-binding motif of EVII is not sufficient for cruciform-DNA binding.

Near-simultaneous DNA cleavage by the subunits of the junction-resolving enzyme T4 endonuclease VII

In common with a number of other DNA junction-resolving enzymes, endonuclease VII of bacteriophage T4 binds to a four-way DNA junction as a dimer, and cleaves two strands of the junction. We have used a supercoil-stabilized cruciform substrate to probe the simultaneity of cleavage at the two sites. Active endonuclease VII converts the supercoiled circular DNA directly into linear product, indicating that the two cleavage reactions must occur within the lifetime of the protein-junction complex. By contrast, a heterodimer of active enzyme and an inactive mutant endonuclease VII leads to the formation of nicked circular product, showing that the subunits operate fully independently.

The resolving enzyme CCE1 of yeast opens the structure of the four-way DNA junction

Junction-resolving enzymes exhibit structure-selective binding to DNA, but may also manipulate the DNA structure. CCE1 is a junction-resolving enzyme found in the yeast mitochondrion. To facilitate the analysis of the CCE1-junction interaction, we have exploited the sequence dependence of the cleavage reaction to devise a junction that is refractory to cleavage by this enzyme, even in the presence of magnesium ions. On binding to four-way DNA junctions, pure recombinant CCE1 opens the global structure into a 4-fold symmetrical configuration of arms with an open, chemically reactive centre. The structure of the CCE1-junction complex is independent of the sequence of the junction, and of the presence or absence of magnesium or other ions. This and other functional properties of CCE1 are strikingly similar to those of RuvC resolving enzyme of Escherichia coli.

Molecular dissection of a LIM domain

LIM domains are novel sequence elements that are found in more than 60 gene products, many of which function as key regulators of developmental pathways. The LIM domain, characterized by the cysteine-rich consensus CX2CX16-23HX2CX2CX2CX16-21 CX2-3(C/H/ D), is a specific mental-binding structure that consists of two distinct zinc-binding subdomains. We and others have recently demonstrated that the LIM domain mediates protein-protein interactions. However, the sequences that define the protein-binding specificity of the LIM domain had not yet been identified. Because structural studies have revealed that the C-terminal zinc-binding module of a LIM domain displays a tertiary fold compatible with nucleic acid binding, it was of interest to determine whether the specific protein-binding activity of a LIM domain could be ascribed to one of its two zinc-binding subdomains. To address this question, we have analyzed the protein-binding capacity of a model LIM peptide, called zLIM1, that is derived from the cytoskeletal protein zyxin. These studies demonstrate that the protein-binding function of zLIM1 can be mapped to sequences contained within its N-terminal zinc-binding module. The C-terminal zinc-binding module of zLIM1 may thus remain accessible to additional interactive partners. Our results raise the possibility that the two structural subdomains of a LIM domain are capable of performing distinct biochemical functions.

T4 endonuclease VII. Importance of a histidine-aspartate cluster within the zinc-binding domain

The DNA junction-resolving enzyme endonuclease VII of bacteriophage T4 contains a zinc-binding region toward the N-terminal end of the primary sequence. In the center of this 39-amino acid section (between residues 38 and 44) lies the sequence HLDHDHE, termed the His-acid cluster. Closely related sequences are found in three other proteins that have similar zinc-binding motifs. We have analyzed the function of these residues by a site-directed mutagenesis approach, modifying single amino acids and studying the properties of the resulting N-terminal protein A fusions. No sequence changes within the His-acid cluster led to a change in zinc content of the protein, indicating that these residues are not involved in the coordination of zinc. We found that the N-terminal aspartate residue (Asp-40) and the two histidine residues (His-41 and His-43) within the cluster are essential for junction-cleavage activity of the proteins. However, all sequence variations within this region generate proteins that retain their ability to bind to four-way DNA junctions (with minor changes in binding affinity in some cases) and to distort their global structure in the same manner as active enzymes. We conclude that the process of cleavage can be uncoupled from those of binding to and distortion of the junction. It is probable that some amino acid side chains of the His-acid cluster participate in the phosphodiester cleavage mechanism of endonuclease VII. The essential aspartate residue might be required for coordination of catalytic metal ions.