Conformational flexibility of the C terminus with implications for substrate binding and catalysis revealed in a new crystal form of deacetoxycephalosporin C synthase

Deacetoxycephalosporin C synthase (DAOCS) from Streptomyces clavuligerus catalyses the oxidative ring expansion of the penicillin nucleus into the nucleus of cephalosporins. The reaction requires dioxygen and 2-oxoglutarate as co-substrates to create a reactive iron-oxygen intermediate from a ferrous iron in the active site. The active enzyme is monomeric in solution. The structure of DAOCS was determined earlier from merohedrally twinned crystals where the last four C-terminal residues (308-311) of one molecule penetrate the active site of a neighbouring molecule, creating a cyclic trimeric structure in the crystal. Shortening the polypeptide chain from the C terminus by more than four residues diminishes activity. Here, we describe a new crystal form of DAOCS in which trimer formation is broken and the C-terminal arm is free. These crystals show no signs of twinning, and were obtained from DAOCS labelled with an N-terminal His-tag. The modified DAOCS is catalytically active. The free C-terminal arm protrudes into the solvent, and the C-terminal domain (residues 268-299) is rotated by about 16 degrees towards the active site. The last 12 residues (300-311) are disordered. Structures for various enzyme-substrate and enzyme-product complexes in the new crystal form confirm overlapping binding sites for penicillin and 2-oxoglutarate. The results support the notion that 2-oxoglutarate and dioxygen need to react first to produce an oxidizing iron species, followed by reaction with the penicillin substrate. The position of the penicillin nucleus is topologically similar in the two crystal forms, but the penicillin side-chain in the new non-twinned crystals overlaps with the position of residues 304-306 of the C-terminal arm in the twinned crystals. An analysis of the interactions between the C-terminal region and residues in the active site indicates that DAOCS could also accept polypeptide chains as ligands, and these could bind near the iron.     

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.     

Resolution of Holliday junction analogs by T4 endonuclease VII can be directed by substrate structure

Endonuclease VII is an enzyme from bacteriophage T4 capable of resolving four-arm Holliday junction intermediates in recombination. Since natural Holliday junctions have homologous (2-fold) sequence symmetry, they can branch migrate, creating a population of substrates that have the branch point at different sites. We have explored the substrate requirements of endonuclease VII by using immobile analogs of Holliday junctions that lack this homology, thereby situating the branch point at a fixed site in the molecule. We have found that immobile junctions whose double-helical arms contain fewer than nine nucleotide pairs do not serve as substrates for resolution by endonuclease VII. Scission of substrates with 2-fold symmetrically elongated arms produces resolution products that are a function of the particular arms that are lengthened. We have confirmed that the scission products are those of resolution, rather than nicking of individual strands, by using shamrock junction molecules formed from a single oligonucleotide strand. A combination of end-labeled and internally labeled shamrock molecules has been used to demonstrate that all of the scission is due to coordinated cleavage of DNA on opposite sides of the junction, 3' to the branch point. Endonuclease VII is known to cleave the crossover strands of Holliday junctions in this fashion. The relationship of the long arms to the cleavage direction suggests that the portion of the enzyme which requires the minimum arm length interacts with the pair of arms containing the 3' portion of the crossover strands on the bound surface of the antiparallel junction.     

The use of resolvases T4 endonuclease VII and T7 endonuclease I in mutation detection

Mutation and polymorphism detection is of increasing importance in the field of molecular genetics. This is reflected by the plethora of chemical, enzymatic, and physically based methods of mutation detection. The ideal method would detect mutations in large fragments of DNA and position them to single base-pair (bp) accuracy. Few methods are able to quickly screen kilobase lengths of DNA and position the mutation at the same time. The Enzyme Mismatch Cleavage (EMC) method of mutation detection is able to reliably detect nearly 100% of mutations in DNA fragments as large as 2 kb and position them to within 6 bp. This method exploits the activity of a resolvase enzyme from T4, T4 endonuclease VII, and more recently, a second bacteriophage resolvase, T7 endonuclease I. The technique uses these enzymes to digest heteroduplex DNA formed by annealing wild-type and mutant DNA. Digestion fragments indicate the presence, and the position, of any mutations. The method is robust and reliable and much faster and cheaper than sequencing. These attributes have resulted in its increasing use in the field of mutation detection.     

Structural flexibility in Trypanosoma brucei enolase revealed by X-ray crystallography and molecular dynamics

Enolase is a validated drug target in Trypanosoma brucei. To better characterize its properties and guide drug design efforts, we have determined six new crystal structures of the enzyme, in various ligation states and conformations, and have carried out complementary molecular dynamics simulations. The results show a striking structural diversity of loops near the catalytic site, for which variation can be interpreted as distinct modes of conformational variability that are explored during the molecular dynamics simulations. Our results show that sulfate may, unexpectedly, induce full closure of catalytic site loops whereas, conversely, binding of inhibitor phosphonoacetohydroxamate may leave open a tunnel from the catalytic site to protein surface offering possibilities for drug development. We also present the first complex of enolase with a novel inhibitor 2-fluoro-2-phosphonoacetohydroxamate. The molecular dynamics results further encourage efforts to design irreversible species-specific inhibitors: they reveal that a parasite enzyme-specific lysine may approach the catalytic site more closely than crystal structures suggest and also cast light on the issue of accessibility of parasite enzyme-specific cysteines to chemically modifying reagents. One of the new sulfate structures contains a novel metal-binding site IV within the catalytic site cleft.     

Initiation of heteroduplex-loop repair by T4-encoded endonuclease VII in vitro.

Heteroduplex DNAs with single-stranded loops of 51 nt or 8 nt were constructed in vitro and used in reactions with purified endonuclease VII (endo VII) from phage T4. The enzyme makes double-strand breaks by introducing pairs of staggered nicks flanking the loops. Regardless of loop-size the nicking sites map exclusively at the 3' side of the loop in the looping strand and at the 3' side of the base of the loop in the non-looping strand. The number of potential cleavage sites is small (less than 5) and their distribution depends on DNA sequence. The two closest staggered nicks are 4 bp apart, 2 bp on either side of the loop. Nicking always occurs in the double-stranded part of the molecules; the single-stranded loops are not attacked by endo VII. The nicks are introduced in a stepwise fashion and selection of the strand for the first nick depends on the sequence of 31 base pairs flanking the loops.     

Pyrimidine dimer dependent cleavage of single-stranded DNA by T4 UV endonuclease

T4 UV endonuclease cleaves double- and single-stranded DNA with equal specificity for photo-pyrimidine dimers. Thus, the enzyme can be used for mapping and quantifying pyrimidine dimers in single-stranded DNA as well as in double-stranded DNA. Mapping of pyrimidine dimers shows that rates of UV-dimerization are not only affected by 5', 3' adjacent bases, but also by position within pyrimidine tracts. Di-pyrimidines at 3' ends of tracts are more photoreactive than those at 5' ends.     

Efficient substrate cleavage catalyzed by hammerhead ribozymes derivatized with selenium for X-ray crystallography

Because oxygen and selenium are in the same group (Family VI) in the periodic table, the site-specific mutagenesis at the atomic level by replacing RNA oxygen with selenium can provide insights on the structure and function of catalytic RNAs. We report here the first Se-derivatized ribozymes transcribed with all nucleoside 5'-(alpha-P-seleno)triphosphates (NTPalphaSe, including A, C, G, and U). We found that T7 RNA polymerase recognizes NTPalphaSe Sp diastereomers as well as the natural NTPs, whereas NTPalphaSe Rp diastereomers are neither substrates nor inhibitors. We also demonstrated the catalytic activity of these Se-derivatized hammerhead ribozymes by cleaving the RNA substrate, and we found that these phosphoroselenoate ribozymes can be as active as the native one. These hammerhead ribozymes site-specifically mutagenized by selenium reveal the close relationship between the catalytic activities and the replaced oxygen atoms, which provides insight on the participation of oxygen in catalysis or intramolecular interaction. This demonstrates a convenient strategy for the mechanistic study of functional RNAs. In addition, the active ribozymes site-specifically derivatized by selenium will allow for convenient MAD phasing in X-ray crystal structure studies.     

Bacteriophage T4 endonuclease II: concerted single-strand nicks yield double-strand cleavage

In vivo, endonuclease II (EndoII) of coliphage T4 cleaves sites with conserved sequence elements (CSEs) to both the left and the right of the cleaved bonds, 16 bp altogether with some variability tolerated. In vitro, however, single-strand nicks in the lower strand predominate at sites containing only the left-side CSE that determines the precise position of lower strand nicks. Upper strand nick positions vary both in vivo and in vitro. A 24 bp substrate was nicked with the same precision as in longer substrates, showing that the conserved sequence suffices for precise nicking by EndoII. Using DNA ligase in vitro, we found that EndoII nicked both strands simultaneously at an in vivo-favoured site but not at an in vitro-favoured site. This indicates that the right-side CSE at in vivo-favoured sites is important for simultaneous nicking of both strands, generating double-strand cleavage. Separate analysis of the two strands following in vitro digestion at two in vitro-favoured sites showed that EndoII nicked the lower strand about 1.5-fold faster than the upper strand. In addition, the upper and lower strands were nicked independently of each other, seldom resulting in double-strand cleavage. Thus, cleavage by EndoII is the fortuitous outcome of two separate nicking events.     

DNA binding and cleavage by the HNH homing endonuclease I-HmuI

The structure of I-HmuI, which represents the last family of homing endonucleases without a defining crystallographic structure, has been determined in complex with its DNA target. A series of diverse protein structural domains and motifs, contacting sequential stretches of nucleotide bases, are distributed along the DNA target. I-HmuI contains an N-terminal domain with a DNA-binding surface found in the I-PpoI homing endonuclease and an associated HNH/N active site found in the bacterial colicins, and a C-terminal DNA-binding domain previously observed in the I-TevI homing endonuclease. The combination and exchange of these features between protein families indicates that the genetic mobility associated with homing endonucleases extends to the level of independent structural domains. I-HmuI provides an unambiguous structural connection between the His-Cys box endonucleases and the bacterial colicins, supporting the hypothesis that these enzymes diverged from a common ancestral nuclease.     

Interaction of a four-way junction in DNA with T4 endonuclease VII

The binding of a synthetic four-way junction in DNA by T4 endonuclease VII has been studied using gel retardation and footprint analysis. Two specific protein-DNA complexes have been observed, but only one is stable in the presence of moderate concentrations of salt. The footprint of T4 endonuclease VII in the salt-resistant complex has been probed using hydroxyl radicals generated by the reaction of iron(II)/EDTA with hydrogen peroxide. The hydroxyl radical cleavage pattern indicates protection of approximately 5 residues in two strands that are diametrically opposed across the junction point.     

Mechanism of DNA cleavage and substrate recognition by a bovine apurinic endonuclease

The location of the phosphodiester bond cleaved by homogeneous Mg2+-dependent apurinic endodeoxyribonuclease (EC 3.1.25.2; APE) of bovine calf thymus has been determined by using a 21-mer oligonucleotide containing a single central apurinic site as a substrate. A single product of cleavage consistent with cleavage of the oligonucleotide 5' to the apurinic site, and leaving a 3' hydroxyl group, was identified. This enzyme is, therefore, a class II apurinic endonuclease. The substrate specificities of this enzyme have been determined by using a variety of natural and synthetic DNAs or oligonucleotides containing base-free sites. Calf thymus APE has an absolute requirement for a double-stranded DNA and requires an abasic site as a substrate. The presence of a base fragment such as a urea residue, an alkoxyamine group attached to the C'-1 position of the abasic site, or reduction of the C'-1 aldehyde abolishes the APE activity of this enzyme. Synthetic abasic sites containing either ethylene glycol, propanediol, or tetrahydrofuran interphosphate linkages are excellent substrates for bovine APE. These results indicate that APE has no absolute requirement for either ring-opened or ring-closed deoxyribose moieties in its recognition of DNA-cleavage substrates. The enzyme may interact with the pocket in duplex DNA that results from the base loss or with the altered conformations of the phosphodiester backbone that result from the abasic site.     

Cleavage specificity of bacteriophage T4 endonuclease VII and bacteriophage T7 endonuclease I on synthetic branch migratable Holliday junctions

Holliday junctions are intermediate structures that are formed and resolved during the process of genetic recombination. To investigate the interaction of junction-resolving nucleases with synthetic Holliday junctions that contain homologous arm sequences, we constructed substrates in which the junction point was free to branch migrate through 26 base-pairs of homology. In the absence of divalent cations, we found that both phage T4 endonuclease VII and phage T7 endonuclease I bound the synthetic junctions to form specific protein-DNA complexes. Such complexes were not observed in the presence of Mg2+, since the Holliday junctions were resolved by the introduction of symmetrical cuts in strands of like polarity. The major sites of cleavage were identified and found to occur within the boundaries of homology. T4 endonuclease VII showed a cleavage preference for the 3' side of thymine bases, whereas T7 endonuclease I preferentially cut the DNA between two pyrimidine residues. However, cleavage was not observed at all the available sites, indicating that in addition to their structural requirements, the endonucleases show strong site preferences.     

Gene 49 endonuclease VII is not essential for multiplicity reactivation of bacteriophage T4

Summary Endonuclease VII, the product of phage T4 gene 49, has been shown previously to resolve Holliday structures in vitro. Two different processes, genetic recombination and multiplicity reactivation are presumed to have Holliday structure intermediates. Other workers have shown that genetic recombination is reduced in a gene 49 mutant infection. However, in the present study, multiplicity reactivation of UV-irradiated ts or amber mutant phage defective in gene 49 was nearly identical to that of UV-irradiated wild-type phage T4. Thus endonuclease VII is not thought to be essential for multiplicity reactivation of phage T4.     

Conformational flexibility in the apolipoprotein E amino-terminal domain structure determined from three new crystal forms: implications for lipid binding

An amino-terminal fragment of human apolipoprotein E3 (residues 1-165) has been expressed and crystallized in three different crystal forms under similar crystallization conditions. One crystal form has nearly identical cell dimensions to the previously reported orthorhombic (P2(1)2(1)2(1)) crystal form of the amino-terminal 22 kDa fragment of apolipoprotein E (residues 1-191). A second orthorhombic crystal form (P2(1)2(1)2(1) with cell dimensions differing from the first form) and a trigonal (P3(1)21) crystal form were also characterized. The structures of the first orthorhombic and the trigonal form were determined by seleno-methionine multiwavelength anomalous dispersion, and the structure of the second orthorhombic form was determined by molecular replacement using the structure from the trigonal form as a search model. A combination of modern experimental and computational techniques provided high-quality electron-density maps, which revealed new features of the apolipoprotein E structure, including an unambiguously traced loop connecting helices 2 and 3 in the four-helix bundle and a number of multiconformation side chains. The three crystal forms contain a common intermolecular, antiparallel packing arrangement. The electrostatic complimentarity observed in this antiparallel packing resembles the interaction of apolipoprotein E with the monoclonal antibody 2E8 and the low density lipoprotein receptor. Superposition of the model structures from all three crystal forms reveals flexibility and pronounced kinks in helices near one end of the four-helix bundle. This mobility at one end of the molecule provides new insights into the structural changes in apolipoprotein E that occur with lipid association.     

Purification and substrate specificity of a T4 phage intron-encoded endonuclease.

The T4 phage td intron-encoded endonuclease (I-Tev I) cleaves the intron-deleted td gene (td delta I) 23 nucleotides upstream of the intron insertion site on the noncoding strand and 25 nucleotides upstream of this site on the coding strand, to generate a 2-base hydroxyl overhang in the 3' end of each DNA strand. I-Tev I-157, a truncated form in which slightly more than one third (88 residues) of the endonuclease is deleted, was purified to homogeneity and shown to possess endonuclease activity similar to that of I-TEV I, the full-length enzyme (245 residues). The minimal length of the td delta I gene that was cleaved by I-Tev I and I-Tev I-157 has been determined to be exactly 39 basepairs, from -27 (upstream in exon1) to +12 (downstream in exon2) relative to the intron insertion site. Similar to the full-length endonuclease, I-Tev I-157 cuts the intronless thymidylate synthase genes from such diverse organisms as Escherichia coli, Lactobacillus casei and the human. The position and nature of the in vitro endonucleolytic cut in these genes are homologous to those in td delta I. Point mutational analysis of the td delta I substrate based on the deduced consensus nucleotide sequence has revealed a very low degree of specificity on either side of the cleavage site, for both the full-length and truncated I-TEV I.     

Conformational changes and cleavage by the homing endonuclease I-PpoI: a critical role for a leucine residue in the active site

The homing endonuclease I-PpoI severely bends its DNA target, resulting in significant deformations of the minor and major groove near the scissile phosphate groups. To study the role of conformational changes within the protein catalyst and the DNA substrate, we have determined the structure of the enzyme in the absence of bound DNA, performed gel retardation analyses of DNA binding and bending, and have mutagenized a leucine residue that contacts an adenine nucleotide at the site of cleavage. The structure of the L116A/DNA complex has been determined and the effects of the mutation on affinity and catalysis have been measured. The wild-type protein displays a rigid-body rotation of its individual subunits upon DNA binding. Homing site DNA is not detectably bent in the absence of protein, but is sharply bent in both the wild-type and L116A complexes. These results indicate that binding involves a large distortion of the DNA and a smaller change in protein conformation. Leucine 116 is critical for binding and catalysis: it appears to be important for forming a well-ordered protein-DNA complex at the cleavage site, for maximal deformation of the DNA, and for desolvation of the nucleotide bases that are partially unstacked in the enzyme complex.