Characterization of an altered DNA catalysis of a camptothecin-resistant eukaryotic topoisomerase I

We investigated topoisomerase I activity at a specific camptothecin-enhanced cleavage site by use of a partly double-stranded DNA substrate. The cleavage site belongs to a group of DNA topoisomerase I sites which is only efficiently cleaved by wild-type topoisomerase I (topo I-wt) in the presence of camptothecin. With a mutated camptothecin-resistant form of topoisomerase I (topo I-K5) previous attempts to reveal cleavage activity at this site have failed. On this basis it was questioned whether the mutant enzyme has an altered DNA sequence recognition or a changed rate of catalysis at the site. Utilizing a newly developed assay system we demonstrate that topo I-K5 not only recognizes and binds to the strongly camptothecin-enhanced cleavage site but also has considerable cleavage/religation activity at this particular DNA site. Thus, topo I-K5 has a 10-fold higher rate of catalysis and a 10-fold higher affinity for DNA relative to topo I-wt. Our data indicate that the higher cleavage/religation activity of topo I-K5 is a result of improved DNA binding and a concomitant shift in the equilibrium between cleavage and religation towards the religation step. Thus, a recently identified point mutation which characterizes the camptothecin-resistant topo I-K5 has altered the enzymatic catalysis without disturbing the DNA sequence specificity of the enzyme.     

Conformational properties and stability of tyrosine hydroxylase studied by infrared spectroscopy. Effect of iron/catecholamine binding and phosphorylation

The conformation and stability of recombinant tetrameric human tyrosine hydroxylase isoenzyme 1 (hTH1) was studied by infrared spectroscopy and by limited tryptic proteolysis. Its secondary structure was estimated to be 42% alpha-helix, 35% beta-extended structures (including beta-sheet), 14% beta-turns, and 10% nonstructured conformations. Addition of Fe(II) or Fe(II) plus dopamine to the apoenzyme did not significantly modify its secondary structure. However, an increased thermal stability and resistance to proteolysis, as well as a decreased cooperativity in the thermal denaturation transition, was observed for the ligand-bound forms. Thus, as compared with the apoenzyme, the ligand-bound subunits of hTH1 showed a more compact tertiary structure but weaker intersubunit contacts within the protein tetramer. Phosphorylation of the apoenzyme by cyclic AMP-dependent protein kinase did not change its overall conformation but allowed on iron binding a conformational change characterized by an increase (about 10%) in alpha-helix and protein stability. Our results suggest that the conformational events involved in TH inhibition by catecholamines are mainly related to modifications of tertiary and quaternary structural features. However, the combined effect of iron binding and phosphorylation, which activates the enzyme, also involves modifications of the protein secondary structure.     

Conversion of bovine pancreatic DNase I to a repair endonuclease with a high selectivity for abasic sites

Bovine pancreatic deoxyribonuclease I (DNase I) is a nuclease of relatively low specificity which interacts with DNA in the minor groove. No contacts are made between the protein and the major groove of the nucleic acid. DNase I is structurally homologous to exonuclease III, a DNA-repair enzyme with multiple activities. One of the main differences between the two enzymes is the presence of an additional alpha-helix in exonuclease III, in a position suggestive of interaction with the major groove of DNA. Recombinant DNA techniques have been used to add 14 amino acids, comprising the 10 amino acids of the exonuclease III alpha-helix flanked by a glycine rich region, to DNase I. The polypeptide has been inserted after serine 174, an amino acid on the surface of DNase I corresponding to the location of the extra alpha-helix in exonuclease III. The recombinant protein, DNase-exohelix, has been purified and its catalytic activities towards DNA investigated. The recombinant protein demonstrated a high selectivity for endonucleolytic cleavage at abasic sites in DNA, a property of exonuclease III but not native DNase I. Thus the insertion of 14 amino acids at Ser174, converts DNase I to an exonuclease III-like enzyme with DNA-repair properties.     

Transfusion virology: progress and challenges

DNA polymerase from Sulfolobus solfataricus, strain MT4 (Sso DNA pol), was one of the first archaeal DNA polymerases to be isolated and characterized. Its encoding gene was cloned and sequenced, indicating that Sso DNA pol belongs to family B of DNA polymerases. By limited proteolysis experiments carried out on the recombinant homogeneous protein, we were able to demonstrate that the enzyme has a modular organization of its associated catalytic functions (DNA polymerase and 3'-5' exonuclease). Indeed, the synthetic function was ascribed to the enzyme C-terminal portion, whereas the N-terminal half was found to be responsible for the exonucleolytic activity. In addition, partial proteolysis studies were utilized to map conformational changes on DNA binding by comparing the cleavage map in the absence or presence of nucleic acid ligands. This analysis allowed us to identify two segments of the Sso DNA pol amino acid chain affected by structural modifications following nucleic acid binding: region 1 and region 2, in the middle and at the C-terminal end of the protein chain, respectively. Site-directed mutagenesis studies will be performed to better investigate the role of these two protein segments in DNA substrate interaction.     

An inhibitor of DNA topoisomerase I from Xenopus laevis ovaries

A novel, heat-resistant and Pronase-sensitive, inhibitor of eukaryotic DNA topoisomerase I has been purified from Xenopus laevis ovaries. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of the most purified fraction revealed three bands with apparent molecular masses of 25, 28.5, and 33.5 kDa. The 25- and 33.5-kDa peptides recovered from an SDS-PAGE gel inhibited X. laevis DNA topoisomerase I. The purified inhibitor was specific to DNA topoisomerase I and did not inhibit other DNA enzymes tested. The inhibitor blocked the catalytic activity of DNA topoisomerase I by interacting with the enzyme, rather than by competing for binding sites on substrate DNA. Binding of DNA topoisomerase I to substrate DNA was blocked by the inhibitor, as was the cleavage reaction catalyzed by DNA topoisomerase I. Inhibition of DNA topoisomerase I was relieved by divalent cations Ca2+, Mg2+, or Mn2+.     

Lead exposure in the general population of the Metropolitan Area of Barcelona: blood levels and related factors

Bacterial and archeal type I topoisomerases, including topoisomerase I, topoisomerase III and reverse gyrase, have different potential roles in the control of DNA topology including regulation of supercoiling and maintenance of genetic stability. Analysis of their coding sequences in different organisms shows that they belong to the type IA family of DNA topoisomerases, but there is variability in organization of various enzymatic domains necessary for topoisomerase activity. The torus-like structure of the conserved transesterification domain with the active site tyrosine for DNA cleavage/rejoining suggests steps of enzyme conformational change driven by DNA substrate and Mg(II) cofactor binding, that are required for catalysis of change in DNA linking number.     

Nucleotide-induced conformational changes in the ATPase and substrate binding domains of the DnaK chaperone provide evidence for interdomain communication

Interactions of the DnaK (Hsp70) chaperone from Escherichia coli with substrates are controlled by ATP. Nucleotide-induced changes in DnaK conformation were investigated by monitoring changes in tryptic digestion pattern and tryptophan fluorescence. Using nucleotide-free DnaK preparations, not only the known ATP-induced major changes in kinetics and pattern of proteolysis but also minor ADP-induced changes were detected. Similar ATP-induced conformational changes occurred in the DnaK-T199A mutant protein defective in ATPase activity, demonstrating that they result from binding, not hydrolysis, of ATP. N-terminal sequencing and immunological mapping of tryptic fragments of DnaK identified cleavage sites that, upon ATP addition, appeared within the proposed C-terminal substrate binding region and disappeared in the N-terminal ATPase domain. They hence reflect structural alterations in DnaK correlated to substrate release and indicate ATP-dependent domain interactions. Domain interactions are a prerequisite for efficient tryptic degradation as fragments of DnaK comprising the ATPase and C-terminal domains were highly protease-resistant. Fluorescence analysis of the N-terminally located single tryptophan residue of DnaK revealed that the known ATP-induced alteration of the emission spectrum, proposed to result directly from conformational changes in the ATPase domain, requires the presence of the C-terminal domain and therefore mainly results from altered domain interaction. Analyses of the C-terminally truncated DnaK163 mutant protein revealed that nucleotide-dependent interdomain communication requires a 15-kDa segment assumed to constitute the substrate binding site.     

UV resonance Raman-selective amide vibrational enhancement: quantitative methodology for determining protein secondary structure

We have directly determined the amide band resonance Raman spectra of the "average" pure alpha-helix, beta-sheet, and unordered secondary structures by exciting within the amide pi-->pi* transitions at 206.5 nm. The Raman spectra are dominated by the amide bands of the peptide backbone. We have empirically determined the average pure alpha-helix, beta-sheet, and unordered resonance Raman spectra from the amide resonance Raman spectra of 13 proteins with well-known X-ray crystal structures. We demonstrate that we can simultaneously utilize the amide I, II, and III bands and the Calpha-H amide bending vibrations of these average secondary structure spectra to directly determine protein secondary structure. The UV Raman method appears to be complementary, and in some cases superior, to the existing methods, such as CD, VCD, and absorption spectroscopy. In addition, the spectra are immune to the light-scattering artifacts that plague CD, VCD, and IR absorption measurements. Thus, it will be possible to examine proteins in micelles and other scattering media.     

Mutations of vaccinia virus DNA topoisomerase I that stabilize the cleavage complex

Two mutations in vaccinia virus topoisomerase I, K167D and G226N, have been characterized. SOS induction was observed in Escherichia coli expressing vaccinia topoisomerase I with either one of these mutations. The mutant enzymes were purified to homogeneity and compared with the wild type enzyme for relaxation activity and the partial activities of substrate binding, site-specific DNA cleavage and DNA religation to determine the mechanism of SOS induction. The K167D mutant enzyme had reduced binding affinity for the DNA substrate with a Kapp that was 10-fold higher than wild type. Nevertheless, in reactions with high enzyme concentration, its substrate cleavage activity was 90% that of wild type. The G226N mutant enzyme had virtually wild type binding and cleavage activities. However, intermolecular religation by these two mutants were observed to be significantly reduced. The cleavage complexes formed with the K167D and G226N mutants were more stable to high salt than the wild type cleavable complex. We propose that these mutants in vivo induce the SOS response in E. coli due to the shift of topoisomerase cleavage-religation equilibrium towards cleavage and increased stability of the cleavage complex. The mutation thus has a similar effect as the topoisomerase-targeting inhibitors that turn topoisomerases into DNA damaging agents.     

Analysis of a core domain in Drosophila DNA topoisomerase II. Targeting of an antitumor agent ICRF-159

To investigate the biochemical properties of individual domains of eukaryotic topoisomerase (topo) II, two truncation mutants of Drosophila topo II were generated, ND406 and core domain. Both mutants lack the ATPase domain, corresponding to the N-terminal 406 amino acid residues in Drosophila protein. The core domain also lacks 240 amino acid residues of the hydrophilic C-terminal region. The mutant proteins have lost DNA strand passage activity while retaining the ability to cleave the DNA and the sequence preference in protein/DNA interaction. The cleavage experiments carried out in the presence of several topo II poisons suggest that the core domain is the key target for these drugs. We have used glass-fiber filter binding assay and CsCl density gradient ultracentrifugation to monitor the formation of a salt-stable, protein-clamp complex. Both truncation mutant proteins can form a clamp complex in the presence of an antitumor agent, ICRF-159, suggesting that the drug targets the core domain of the enzyme and promotes the intradimeric closure at the N-terminal interface of the core domain. Furthermore, the salt stability of the closed protein clamp induced by ICRF-159 depends on the presence and closure of the N-terminal ATPase domain.     

Characterization of the three-dimensional solution structure of human profilin: 1H, 13C, and 15N NMR assignments and global folding pattern

Human profilin is a 15-kDa protein that plays a major role in the signaling pathway leading to cytoskeletal rearrangement. Essentially complete assignment of the 1H, 13C, and 15N resonances of human profilin have been made by analysis of multidimensional, double- and triple-resonance nuclear magnetic resonance (NMR) experiments. The deviation of the 13C alpha and 13C beta chemical shifts from their respective random coil values were analyzed and correlate well with the secondary structure determined from the NMR data. Twenty structures of human profilin were refined in the program X-PLOR using a total of 1186 experimentally derived conformational restraints. The structures converged to a root mean squared distance deviation of 1.5 A for the backbone atoms. The resultant conformational ensemble indicates that human profilin is an alpha/beta protein comprised of a seven-stranded, antiparallel beta-sheet and three helices. The secondary structure elements for human profilin are quite similar to those found in Acanthamoeba profilin I [Archer, S. J., Vinson, V. K., Pollard, T. D., & Torchia, D. A. (1993), Biochemistry 32, 6680-6687], suggesting that the three-dimensional structure of Acanthamoeba profilin I should be analogous to that determined here for human profilin. The structure determination of human profilin has facilitated the sequence alignment of lower eukaryotic and human profilins and provides a framework upon which the various functionalities of profilin can be explored. At least one element of the actin-binding region of human profilin is an alpha-helix. Two mechanisms by which phosphatidylinositol 4,5-bisphosphate can interfere with actin-binding by human profilin are proposed.     

Class sigma glutathione transferase unfolds via a dimeric and a monomeric intermediate: impact of subunit interface on conformational stability in the superfamily

Solvent-induced equilibrium unfolding of a homodimeric class sigma glutathione transferase (GSTS1-1, EC 2.5.1.18) was characterized by tryptophan fluorescence, anisotropy, enzyme activity, 8-anilino-1-naphthalenesulfonate (ANS) binding, and circular dichroism. Urea induces a triphasic unfolding transition with evidence for two well-populated thermodynamically stable intermediate states of GSTS1-1. The first unfolding transition is protein concentration independent and involves a change in the subunit tertiary structure yielding a partially active dimeric intermediate (i.e., N2 left and right arrow I2). This is followed by a protein concentration dependent step in which I2 dissociates into compact inactive monomers (M) displaying enhanced hydrophobicity. The third unfolding transition, which is protein concentration independent, involves the complete unfolding of the monomeric state. Increasing NaCl concentrations destabilize N2 and appear to shift the equilibrium toward I2 whereas the stability of the monomeric intermediate M is enhanced. The binding of substrate or product analogue (i.e., glutathione or S-hexylglutathione) to the protein's active site stabilizes the native dimeric state (N2), causing the first two unfolding transitions to shift toward higher urea concentrations. The stability of M was not affected. The data implicate a region at/near the active site in domain I (most likely alpha-helix 2) as being highly unstable/flexible which undergoes local unfolding, resulting initially in I2 formation followed by a disruption in quaternary structure to a monomeric intermediate. The unfolding/refolding pathway is compared with those observed for other cytosolic GSTs and discussed in light of the different structural features at the subunit interfaces, as well as the evolutionary selection of this GST as a lens crystallin.     

Sequence-specific DNA binding by EcoKI, a type IA DNA restriction enzyme

The type I DNA restriction and modification enzymes of prokaryotes are multimeric enzymes that cleave unmethylated, foreign DNA in a complex process involving recognition of the methylation status of a DNA target sequence, extensive translocation of DNA in both directions towards the enzyme bound at the target sequence, ATP hydrolysis, which is believed to drive the translocation possibly via a helicase mechanism, and eventual endonucleolytic cleavage of the DNA. We have examined the DNA binding affinity and exonuclease III footprint of the EcoKI type IA restriction enzyme on oligonucleotide duplexes that either contain or lack the target sequence. The influence of the cofactors, S-adenosyl methionine and ATP, on binding to DNA of different methylation states has been assessed. EcoKI in the absence of ATP, with or without S-adenosyl methionine, binds tightly even to DNA lacking the target site and the exonuclease footprint is large, approximately 45 base-pairs. The protection is weaker on DNA lacking the target site. Partially assembled EcoKI lacking one or both of the subunits essential for DNA cleavage, is unable to bind tightly to DNA lacking the target site but can bind tightly to the recognition site. The addition of ATP to EcoKI, in the presence of AdoMet, allows tight binding only to the target site and the footprint shrinks to 30 base-pairs, almost identical to that of the modification enzyme which makes up the core of EcoKI. The same effect occurs when S-adenosyl homocysteine or sinefungin are substituted for S-adenosyl methionine, and ADP or ATPgammaS are substituted for ATP. It is proposed that the DNA binding surface of EcoKI comprises three regions: a "core" region which recognises the target sequence and which is present on the modification enzyme, and a region on each DNA cleavage subunit. The cleavage subunits make tight contacts to any DNA molecule in the absence of cofactors, but this contact is weakened in the presence of cofactors to allow the protein conformational changes required for DNA translocation when a target site is recognised by the core modification enzyme. This weakening of the interaction between the DNA cleavage subunits and the DNA could allow more access of exonuclease III to the DNA and account for the shorter footprint.     

Structure and thermal stability of photosystem II reaction centers studied by infrared spectroscopy

The secondary structure of photosystem II reaction centers isolated from pea has been deduced from quantitative analysis of the component bands of the infrared amide I spectral region, determined by FTIR spectroscopy. The analysis shows the isolated complex to consist of 40% alpha-helix, 10% beta-sheet, 14% beta-strands (or extended chains), 17% turns, 15% loops, and 3% nonordered segments. These structural protein elements were determined for samples in H2O, in D2O, and in dried films. The isolated reaction center, composed of proteins D1,D2,cytochrome b559, and PsbI, has been predicted to contain a total of 13 transmembrane alpha-helices, which conveys a percentage of this type of structure congruent with the structural determination deduced from FTIR spectra. The process of thermal destabilization of the reaction centers has also been studied by FTIR spectroscopy, showing a clear main conformational transition at 42 degrees C, which indicates a high thermal sensitivity of the secondary structure of this protein complex. Such thermal instability may correlate with the well-described high sensitivity of photosystem II to damage and may relate to the process of rapid protein degradation that photosystem II suffers during photoinhibition of plants.     

The thermal stability and domain interactions of the mannitol permease of Escherichia coli. A differential scanning calorimetry study

The thermal stability and domain interactions in the mannitol transporter from Escherichia coli, enzyme IImtl, have been studied by differential scanning calorimetry. To this end, the wild type enzyme, IICBAmtl, as well as IICBmtl and IICmtl, were reconstituted into a dimyristoylphosphatidylcholine lipid bilayer. The changes in the gel to liquid crystalline transition of the lipid indicated that the protein was inserted into the membrane, disturbing a total of approximately 40 lipid molecules/protein molecule. The thermal unfolding profile of EIImtl exhibited three separate transitions, two of which were overlapping, that could be assigned to structural domains in the protein. Treatment with trypsin, resulting in the degradation of the water-soluble part of the enzyme while leaving the binding and translocation capability of the enzyme intact, resulted in a decrease of the Tm and enthalpy of unfolding of the membrane-embedded C domain. This effect was much more apparent in the presence of the substrate but only partly so in the presence of the substrate analog perseitol. These results are consistent with a recently proposed model (Meijberg, W., Schuurman-Wolters, G. K., and Robillard, G. T. (1998) J. Biol. Chem. 273, 7949-7946), in which the B domain takes part in the conformational changes during the substrate binding process.     

Amide modes of the alpha-helix: Raman spectroscopy of filamentous virus fd containing peptide 13C and 2H labels in coat protein subunits

The filamentous virus fd consists of a single-stranded DNA genome sheathed by 2700 copies of a 50-residue alpha-helical subunit (protein pVIII) and serves as a model assembly of alpha-helices. To advance vibrational assignments for the alpha-helix, we have investigated Raman spectra of fd virions containing 13C and 2H (deuterium) labels at various main-chain sites of the pVIII subunits. 13C was introduced at specific peptide carbonyls, while deuterium was introduced at selected alpha-carbon (Calpha) and amide nitrogen positions. Interpretation of the Raman spectra reveals a previously unrecognized alpha-helix band in the spectral interval 730-745 cm-1, tentatively assigned to a carbonyl in-plane bending mode (amide IV). Experimental evidence has also been obtained for a distinctive alpha-helix marker near 1345 cm-1, assigned to a coupled Calpha-H bending and Calpha-C stretching mode. The fd virions containing 13C-labeled carbonyls exhibit unexpectedly complex amide I profiles, consisting of multiple band components. Amide I splitting resulting from 13C substitution of carbonyls is attributed to decoupling of transition-dipole interactions normally occurring in the extended pVIII helix. The present study identifies novel conformation-dependent Raman bands in a native alpha-helix assembly, confirms amide I and amide III assignments proposed previously for filamentous viruses, and facilitates new Raman assignments for the packaged ssDNA. The alpha-helix markers identified here should also be useful in conformation analyses of other proteins by Raman spectroscopy.     

Volume of resection in patients treated with breast conservation for ductal carcinoma in situ

The N-terminal domain (1-318 amino acids) of mouse NFkappaB (p65) has been purified to homogeneity from the soluble fraction of Escherichia coli cells expressing this protein. Its complex with a full-length ikappaB-alpha (MAD3, 1-317 amino acids) molecule was generated by binding the E. coli-derived ikappaB-alpha to the purified NFkappaB and purifying the complex by sequential chromatography. The stoichiometry of NFkappaB to ikappaB in the complex was determined to be 2 to 1 by light scattering and SDS-polyacrylamide gel electrophoresis. The secondary structure of the NFkappaB (p65) determined by Fourier-transform infrared (FTIR) spectroscopy is in good agreement with that of the p50 in the crystal structure of the p50/DNA complex, indicating that no significant structural change in NFkappaB occurs upon binding of DNA. The FTIR spectrum of the NFkappaB/ikappaB complex indicates that its secondary structure is composed of 17% alpha-helix, 39% beta-strand, 18% irregular structures, and 26% beta-turns and loops. By comparing these data to the FTIR data for NFkappaB alone, it is concluded that the ikappaB (MAD3) in the complex contains 35% alpha-helix, 27% beta-strand, 22% irregular structures, and 16% beta-turns and loops. Circular dichroism (CD) analysis of a shorter form of ikappaB (pp40) indicates that it contains at least 20% alpha-helix and that the ikappaB subunit accounts for nearly all of the alpha-helix present in the NFkappaB/ikappaB complex, consistent with the FTIR results. The stabilities of NFkappaB, ikappaB, and their complex against heat-induced denaturation were investigated by following changes in CD signal. The results indicate that the thermal stability of ikappaB is enhanced upon the formation of the NFkappaB/ikappaB complex.