Bernard A. Connolly

Zebularine: a novel DNA methylation inhibitor that forms a covalent complex with DNA methyltransferases.

Mechanism-based inhibitors of enzymes, which mimic reactive intermediates in the reaction pathway, have been deployed extensively in the analysis of metabolic pathways and as candidate drugs. The inhibition of cytosine-[C5]-specific DNA methyltransferases (C5 MTases) by oligodeoxynucleotides containing 5-azadeoxycytidine (AzadC) and 5-fluorodeoxycytidine (FdC) provides a well-documented example of mechanism-based inhibition of enzymes central to nucleic acid metabolism. Here, we describe the interaction between the C5 MTase from Haemophilus haemolyticus (M.HhaI) and an oligodeoxynucleotide duplex containing 2-H pyrimidinone, an analogue often referred to as zebularine and known to give rise to high-affinity complexes with MTases. X-ray crystallography has demonstrated the formation of a covalent bond between M.HhaI and the 2-H pyrimidinone-containing oligodeoxynucleotide. This observation enables a comparison between the mechanisms of action of 2-H pyrimidinone with other mechanism-based inhibitors such as FdC. This novel complex provides a molecular explanation for the mechanism of action of the anti-cancer drug zebularine.

Uracil recognition in archaeal DNA polymerases captured by X-ray crystallography.

Archaeal family B DNA polymerases bind tightly to template-strand uracil and stall replication on encountering the pro-mutagenic base. This article describes an X-ray crystal structure, at 2.8 A resolution, of Thermococcus gorgonarius polymerase in complex with a DNA primer-template containing uracil in the single-stranded region. The DNA backbone is distorted to position the uracil deeply within a pocket, located in the amino-terminal domain of the polymerase. Specificity arises from a combination of hydrogen bonds between the protein backbone and uracil, with the pocket shaped to prevent the stable binding of the four standard DNA bases. Strong interactions are seen with the two phosphates that flank the uracil and the structure gives clues concerning the coupling of uracil binding to the halting of replication. The importance of key amino acids, identified by the analysis of the structure and their conservation between archaeal polymerases, was confirmed by site-directed mutagenesis. The crystal structure of V93Q, a polymerase variant that no longer recognises uracil, is also reported, explaining the V93Q phenotype by the steric exclusion of uracil from the pocket.

Influence of the Phosphate Backbone on the Recognition and Hydrolysis of DNA by the EcoRV Restriction Endonuclease A STUDY USING OLIGODEOXYNUCLEOTIDE PHOSPHOROTHIOATES

A set of phosphorothioate-containing oligonucleotides based on pGACGATATCGTC, a self-complementary dodecamer that contains the EcoRV recognition sequence (GATATC), has been prepared. The phosphorothioate group has been individually introduced at the central nine phosphate positions and the two diastereomers produced at each site separated and purified. The K and V values found for each of these modified DNA molecules with the EcoRV restriction endonuclease have been determined and compared with those seen for the unmodified all-phosphate-containing dodecamer. This has enabled an evaluation of the roles that both of the non-esterified oxygen atoms in the individual phosphates play in DNA binding and hydrolysis by the endonuclease. The results have also been compared with crystal structures of the EcoRV endonuclease, complexed with an oligodeoxynucleotide, to allow further definition of phosphate group function during substrate binding and turnover. For further study, see the related article “Probing the Indirect Readout of the Restriction Enzyme EcoRV: Mutational Analysis of Contacts to the DNA Backbone” (Wenz, A., Jeltsch, A., and Pingoud, A. (1996) J. Biol. Chem. 271, 5565-5573).

Purification, Characterization, and Role of Nucleases and Serine Proteases in Streptomyces Differentiation ANALOGIES WITH THE BIOCHEMICAL PROCESSES DESCRIBED IN LATE STEPS OF EUKARYOTIC APOPTOSIS

Two exocellular nucleases with molecular masses of 18 and 34 kDa, which are nutritionally regulated and reach their maximum activity during aerial mycelium formation and sporulation, have been detected in Streptomyces antibioticus. Their function appears to be DNA degradation in the substrate mycelium, and in agreement with this proposed role the two nucleases cooperate efficiently with a periplasmic nuclease previously described inStreptomyces antibioticus to completely hydrolyze DNA. The nucleases cut DNA nonspecifically, leaving 5′-phosphate mononucleotides as the predominant products. Both proteins require Mg2+, and the additional presence of Ca2+ notably stimulates their activities. The two nucleases are inhibited by Zn2+and aurin tricarboxylic acid. The 18-kDa nuclease fromStreptomyces is reminiscent of NUC-18, a thymocyte nuclease proposed to have a key role in glucocorticoid-stimulated apoptosis. The 18-kDa nuclease was shown, by amino-terminal protein sequencing, to be a member of the cyclophilin family and also to possess peptidylprolylcis-trans-isomerase activity. NUC-18 has also been shown to be a cyclophilin, and “native” cyclophilins are capable of DNA degradation. The S. antibioticus 18-kDa nuclease is produced by a proteolytic processing from a less active protein precursor. The protease responsible has been identified as a serine protease that is inhibited byN α -p-tosyl-l-lysine chloromethyl ketone and leupeptin. Inhibition of both of the nucleases or the protease impairs aerial mycelium development in S. antibioticus. The biochemical features of cellular DNA degradation during Streptomyces development show significant analogies with the late steps of apoptosis of eukaryotic cells.

Predicting metals sensed by ArsR-SmtB repressors: allosteric interference by a non-effector metal

Many bacterial genomes encode multiple metal‐sensing ArsR‐SmtB transcriptional repressors. There is interest in understanding and predicting their metal specificities. Here we analyse two arsR‐smtB genes, ydeT and yozA (now aseR and czrA) from Bacillus subtilis. Purified AseR and CzrA formed complexes in gel‐retardation and fluorescence‐anisotropy assays with fragments of promoters that were derepressed in ΔaseR and ΔczrA cells. Candidate (i) partly thiolate, α3‐helix (for AseR) and (ii) tetrahedral, non‐thiolate, α5‐helix (for CzrA) metal binding sites were predicted then tested in vitro and/or in vivo. The precedents are for such sites to sense arsenite/antimonite (α3) and zinc (α5). This correlated with the respective metal inducers of AseR and CzrA repressed promoters in B. subtilis and matched the metals that impaired formation of protein–DNA complexes in vitro. The putative sensory sites of 1024 ArsR‐SmtB homologues are reported. Although AseR did not sense zinc in vivo, it bound zinc in vitro exploiting α3 thiols, but AseR DNA binding was not impaired by zinc. If selectivity relies on discriminatory triggering of allostery not just selective metal binding, then tight non‐effector metal complexes could theoretically inhibit metal sensing. AseR remained arsenite‐sensitive in equimolar zinc, while CzrA remained zinc‐sensitive in equimolar arsenite in vitro. However, cupric ions did not impair CzrA–DNA complex formation but did inhibit zinc‐mediated allostery in vitro and prevent zinc binding. Access to copper must be controlled in vivo to avoid formation of cupric CzrA.

Continuous spectrophotometric assay for restriction endonucleases using synthetic oligodeoxynucleotides and based on the hyperchromic effect

A continuous spectrophotometric assay for the EcoRV restriction endonuclease has been developed. The synthetic self-complementary oligonucleotide d(GACGATATCGTC) (which is double stranded under the assay conditions) is used as the substrate. The EcoRV endonuclease recognizes d(GATATC) sequences cutting between the central T and dA bases. Thus d(GACGATATCGTC) is converted to d(GACGAT) and d(pATCGTC) during catalysis. Both of the hexameric products are single stranded under the assay conditions. The conversion of the dodecameric substrate to the two hexameric products and the concomitant change from double- to single-stranded DNA is associated with an increase in absorbance at 254 nm due to the hyperchromic effect. This change can be used to monitor column effluents for endonuclease activity and also for Km and kcat determination under steady-state kinetic conditions.

Immobilisation and synthesis of DNA on Si(111), nanocrystalline porous silicon and silicon nanoparticles.

Oligonucleotides have been synthesized on hydrogen-terminated Si(111) and porous silicon using surface hydrosilation of difunctional molecules (1,(omega)-dimethoxytritylundecenol) to produce a monolayer bearing suitable reactive groups to allow automated solid-phase DNA synthesis. The absence of an intervening oxide enables electrochemical characterisation of the surface-bound oligonucleotides. Complementary sequences to the DNA synthesized on Si(111) undergo hybridisation at the surface and a straightforward electrochemical quantitation of the amount of synthesized DNA and its hybridisation efficiency (47%) is possible using Ru(NH3)6(3+) as a redox label. In the case of DNA synthesized in porous silicon, electron transfer (ET) between DNA and the underlying bulk semiconductor can be studied by cyclic voltammetry, however the anisotropic diffusion inside the porous layer and the large resistance of the porous silicon results in voltammograms for which thin-layer behaviour is not observed and the peak currents increase with the square root of scan rate. We interpret these voltammograms in terms of charge transport limitations in the layer of metal centres bound to the DNA inside the pores. Further evidence for this interpretation has been obtained using scanning electrochemical microscopy (SECM) to study the charge transport between redox species in films of DNA synthesized on Si(111) surfaces that are in contact with an aqueous phase. As the bulk concentration of Ru(NH3)6(3+) is reduced below about 250 microM the SECM feedback indicates that the rate of charge transport between surface-bound Ru(NH3)6(3+) exceeds that due to diffusion in the liquid phase. Electrochemical quantitation of the DNA is not possible in this situation, however we have been able to obtain independent determinations using radioassay based on 32P or UV/VIS spectrophotometry of dimethoxytrityl cation cleaved from the porous layer. In the case of the former, use of labelled complementary sequences shows an inverse relationship between the current density used to prepare the porous silicon and the amount of hybridisation. This can be interpreted in terms of the specific surface area of the porous silicon layers since the hybridisation efficiencies (ca. 40%) obtained by comparing DMT+ cleaved from sequences synthesized on the surface and then from complementary sequences after hybridisation were relatively insensitive to the current density used to prepare the layers. Our recent work has also been concerned with individual Si nanocrystals generated by breaking up porous silicon during thermal hydrosilation reactions. FTIR spectroscopy shows these particles are also coated with an organic Si-C-bonded monolayer and they form stable, non-turbid and strongly luminescent (lambdamax = 600-650 nm) dispersions in apolar solvents (L. H. Lie, M. S. Duerdin, E. M. Tuite, A. Houlton and B. R. Horrocks, J. Electroanal. Chem., 2002, 538/539, 183). The effect of carrying out synthetic reactions on the porous silicon prior to breaking up the layer is to produce instead larger, micron-scale assemblies with a nanometre scale internal structure. Micron-sized particles of porous silicon produced by breaking up the layer can be probed by confocal Raman spectroscopy using the electric field of a focused laser to trap such particles. Although these particles are also luminescent, the use of relatively long wavelength laser excitation (lambda = 785 nm) allows acquisition of Raman spectra from individual particles in the optical trap. The bulk optical phonon mode at ca. 520 cm(-1) characteristic of crystalline silicon is red-shifted and broadened providing evidence for an internal nanometre scale substructure in these micron-sized particles and we also see evidence for this mode in the colloidal suspensions of the Si nanoparticles. We propose a model for the formation of these two types of particles and briefly discuss the prospects to extend our solid-phase synthesis on porous silicon to allow the facile synthesis of luminescent Si nanocrystals bearing DNA or other biomolecules.

The EcoRV Modification Methylase Causes Considerable Bending of DNA upon Binding to Its Recognition Sequence GATATC

The EcoRV methyltransferase modifies DNA by the introduction of a methyl group at the 6-NH position of the first deoxyadenosine in GATATC sequences. The enzyme forms a stable and specific complex with GATATC sequences in the presence of a nonreactive analogue, such as sinefungin, of its natural cofactor S-adenosyl-L-methionine. Using circular permutation band mobility shift analysis (in which the distance between the GATATC sequence and the end of the DNA is varied) of protein-DNA-cofactor complexes we have shown the methylase induces a bend of just over 60° in the bound DNA. This was confirmed by phasing analysis, in which the spacing between the GATATC site and a poly(dA) tract is varied through a helical turn, which showed that the orientation of the induced curve was toward the major groove. There was no significant difference in the bend angle measured using unmethylated GATATC sequences and hemimethylated sequences which contain GATATC in one strand only. These are the natural substrates for the enzyme. The EcoRV endonuclease, a very well characterized protein, served as a positive control. DNA bending by this protein has been previously determined both by crystallographic and solution methods. The two proteins bend DNA toward the major groove but the bend angle produced by the methylase, slightly greater than 60°, is a little larger than that observed with the endonuclease, which is approximately 44°.

Overproduction of the toxic protein, bovine pancreatic DNasel, in Escherichia coli using a tightly controlled T7-promoter-based vector

A synthetic gene coding for bovine pancreatic DNaseI has been cloned under the control of a T7 promoter present on the plasmid pET11. This construct yields a stable Escherichia coli transformant only when transcription from this promoter is tightly controlled. Production of recombinant DNaseI (reDNaseI) is achieved by infection of the cells with a mutant lambda phage, CE6, which carries the gene encoding T7 RNA polymerase. Induced bacterial cultures yield in excess of 2 mg per litre of reDNaseI after purification.

Recognition of deaminated bases by archaeal family-B DNA polymerases.

Archaeal family-B DNA polymerases interact specifically with uracil and hypoxanthine, stalling replication on encountering these deaminated bases in DNA template strands. The present review describes X-ray structural data which elucidate the mechanism of read-ahead recognition of uracil and suggests how this is coupled to cessation of polymerization. The possible role of read-ahead recognition of uracil/hypoxanthine in DNA repair is discussed, as is the observation that the feature appears to be limited to replicative polymerases of the archaeal domain.