[Electrochemical analysis of nucleic acids, proteins and polysaccharides in biomedicine]. / Elektrochemická analýza nukleových kyselin, bílkovin a polysacharidu v bio-medicíne

Electrochemical analysis of nucleic acids, proteins and polysaccharides represents an interesting, although not widely spread alternative to current methods based predominantly on optical detection because it offers a relatively inexpensive, fast and instrumentally simple detection of parallel samples on miniaturized chips, ideal for personalized medicine of the 21st century. Nucleic acid electrochemistry enables, for example, detection of specific DNA sequences (for determination of genes or presence of bacteria and viruses, etc.), DNA damage analysis and interaction with other molecules, DNA methylation or detection of microRNAs as potential cancer bio-markers. In the electrochemistry of proteins, great emphasis is put on construction of immunosensors for capturing specific proteins (antigens) using antibodies, suitable for diagnostics. From a bio-physical point of view, intrinsic electrocatalytic signal of proteins sensitive to conformational changes could be useful in discrimination of mutant proteins (e. g. p53), native and aggregated forms (α-synuclein in Parkinsons disease) or for studies of protein interactions with low molecular  weight ligands and DNA. Due to an increased interest of scientists in glycoproteins, new electrochemical papers emerged aiming at detection of oligosaccharides and polysaccharides (i.e. glycans, when part of the protein). These assays employ for instance electroactive labels specific for saccharides or lectin bio-sensors using lectins which strongly bind glycans. Electrochemical analysis thus appears as an interesting tool in current genomics, proteomics and glycomics, as well as for cancer diagnostics.

Influence of the interfacial peptide organization on the catalysis of hydrogen evolution.

The hydrogen evolution reaction is catalyzed by peptides and proteins adsorbed on electrode materials with high overpotentials for this reaction, such as mercury. The catalytic response characteristics are known to be very sensitive to the composition and structure of the investigated biomolecule, opening the way to the implementation of a label-free, reagentless electroanalytical method in protein analysis. Herein, it is shown using the model peptide Cys-Ala-Ala-Ala-Ala-Ala that the interfacial organization significantly influences the catalytic behavior. This peptide forms at the electrode two distinct films, depending on the concentration and accumulation time. The low-coverage film, composed of flat-lying molecules (area per molecule of approximately 250-290 A(2)), yields a well-defined catalytic peak at potentials around -1.75 V. The high-coverage film, made of upright-oriented peptides (area per molecule of approximately 43 A(2)), is catalytically more active and the peak is observed at potentials less negative by approximately 0.4 V. The higher activity, evidenced by constant-current chronopotentiometry and cyclic voltammetry, is attributed to an increase in the acid dissociation constant of the amino acid residues as a result of the low permittivity of the interfacial region, as inferred from impedance measurements. An analogy is made to the known differences in acidic-basic behaviors of solvent-exposed and hydrophobic domains of proteins.

New approaches in the development of DNA sensors: hybridization and electrochemical detection of DNA and RNA at two different surfaces.

Up to now, the development of the electrochemical DNA hybridization sensors relied on solid electrodes, on which both the hybridization and detection steps have been performed. Here we propose a new method in which the DNA hybridization is performed at commercially available magnetic beads and electrochemical detection on detection electrodes (DE). Due to minimum nonspecific DNA adsorption at the magnetic beads, very high specificity of the DNA hybridization is achieved. Optimum DE can be chosen only with respect to the given electrode process. It is shown that high sensitivity and specificity in the detection of relatively long target DNAs can be obtained (a) by using cathodic stripping voltammetry at mercury or solid mercury amalgam DEs for the determination of purine bases, released from DNA by acid treatment, and (b) by enzyme-linked immunoassay of target DNA modified by osmium tetroxide,2,2'-bipyridine (Os,bipy) at carbon DEs. Direct determination of Os,bipy at mercury and carbon electrodes is also possible.

DNA hybridization at microbeads with cathodic stripping voltammetric detection.

In electrochemical DNA hybridization sensors generally a single-stranded probe DNA was immobilized at the electrode followed by hybridization with the target DNA and electrochemical detection of the hybridization event at the same electrode. In this type of experiments nonspecific adsorption of DNA at the electrode caused serious difficulties especially in the case of the analysis of long target DNAs. We propose a new technology in which DNA is hybridized at a surface H and the hybridization is detected at the detection electrode (DE). This technology significantly extends the choice of hybridization surfaces and DEs. Here we use paramagnetic Dynabeads Oligo(dT)(25) (DBT) as a transportable reactive surface H and a hanging mercury drop electrode as DE. We describe a label-free detection of DNA and RNA (selectively captured at DBT) based on the determination of adenines (at ppb levels, by cathodic stripping voltammetry) released from the nucleic acids by acid treatment. The DNA and RNA nonspecific adsorption at DBT is negligible, making thus possible to detect the hybridization event with a great specificity and sensitivity. Specific detection of the hybridization of polyribonucleotides, mRNA, oligodeoxynucleotides, and a DNA PCR product (226 base pairs) is demonstrated. New possibilities in the development of the DNA hybridization sensors opened by the proposed technology, including utilization of catalytic signals in nucleic acid determination at mercury (e.g. signals of osmium complexes covalently bound to DNA) and solid DEs (e.g. using enzyme-labeled antibodies against chemically modified DNAs) are discussed.

Determination of metallothionein at the femtomole level by constant current stripping chronopotentiometry.

Metallothionein (MT) from rabbit liver was analyzed by differential pulse polarography, cyclic voltammetry, square wave voltammetry, and chronopotentiometric stripping analysis (CPSA) with a hanging mercury drop electrode under various conditions. The highest sensitivity of the MT determination was obtained with CPSA which produced a well-developed peak H due to catalytic hydrogen evolution at highly negative potentials. The highest peak H was obtained in borate buffer close to pH 8.0. In this medium, subnanomolar concentrations of MT were detectable. In the adsorptive transfer stripping (medium exchange) experiments, determination of few femtomoles of MT in 5-microL aliquots of the analyte was possible. CPSA determination of MT in various tissues of carp (Cyprinus carpio) yielded values in agreement with the published data.

Binding of p53 and its core domain to supercoiled DNA.

We have compared the binding of human full-length p53 protein (p53; expressed in bacteria and insects) and its isolated core domain (p53CD, amino acids 94-312; expressed in bacteria) to negatively supercoiled (sc) DNA using gel electrophoresis and immunoblotting. Significant differences were observed; p53CD produced a relatively small and continuous retardation of scDNA, in contrast to the ladder of distinct bands formed by p53 in agarose gels. The ladder produced by full-length protein expressed in bacteria (p53b) was similar to that observed earlier with protein expressed in insect cells (p53i). Competition between scDNAs and their linearized (lin) forms showed a preference for scDNAs by both p53 and p53CD, but the ratios characterizing the distribution of the protein between sc and lin pBluescript DNAs were substantially higher for p53 (sc/lin > 60 in p53b) than for p53CD (sc/lin approximately 4). Strong binding of p53 to scDNA lacking the p53 consensus sequence may represent a new p53-binding mode, which we tentatively denote supercoil-selective (SCS) binding. This binding requires both the C-terminal domain and the core domain. Targets of this binding may include: (a) DNA segments defined both by the nucleotide sequence and local topology, and/or (b) strand crossings and/or bending. The binding preference of p53CD for scDNA may be due to the known nonspecific binding to internal single-stranded regions in scDNA (absent in relaxed DNA molecules) and/or to SCS binding albeit with reduced affinity due to the absence of contributions from other p53 domains.

Precise characterisation of monoclonal antibodies to the C-terminal region of p53 protein using the PEPSCAN ELISA technique and a new non-radioactive gel shift assay.

The development of human cancers is frequently associated with inactivation of the p53 tumour suppressor protein triggering cell cycle arrest or apoptosis in response to cellular stress. The p53 protein has been identified as a transcription factor with sequence-specific DNA binding properties. The DNA-binding activity is cryptic but can be modulated through the C-terminal region of the p53 protein by several different stimuli, including phosphorylation by casein kinase II (CKII), protein kinase C (PKC) or binding of the C-terminal monoclonal antibody PAb421. Monoclonal antibodies to the C-terminal region of p53 protein are able to activate the latent form of p53 and induce binding to DNA. To characterise such antibodies, we used a combination of the PEPSCAN ELISA procedure and a newly developed non-radioactive gel shift assay. Monoclonal antibodies from the Bp53 series displayed higher affinities for the human, rat and mouse p53 proteins than did the conventional antibody PAb421. In addition, these antibodies were able to activate the sequence-specific DNA binding functions in latent forms of p53 protein and, in contrast to PAb421, they were able to recognise both PKC phosphorylated and PKC non-phosphorylated forms of p53 protein. Our monoclonal antibodies recognising post-translationally modified target epitopes in the C-terminal region of p53 protein might assist the development of more effective molecules for p53-based cancer therapy.

Specific modulation of p53 binding to consensus sequence within supercoiled DNA by monoclonal antibodies.

Monoclonal antibodies (MAbs) were used to investigate the binding of insect cell-expressed, wild-type human p53 protein to the consensus sequence (p53CON) in a 474-bp DNA fragment and to supercoiled (sc) DNAs with and without p53CON. Supershifting of p53-DNA complexes by MAbs in agarose gels was applied to studies of activation of p53 for sequence-specific binding within scDNA. C-terminal specific antibody Bp53-10.1 activated the sequence-specific binding of p53 to p53CON within pPGM1 scDNA but did not influence binding of p53 to pBluescript scDNA (not containing p53CON). Incubation of p53 with DO-1 prior to addition of Bp53-10.1 prevented activation of p53 and induced dissociation of a portion of pPGM1 scDNA from the sequence-specific immune complex; no such dissociation was observed if pPGM1 scDNA was replaced by the 474-bp p53CON-containing DNA fragment.

Electrode potential-modulated cleavage of surface-confined DNA by hydroxyl radicals detected by an electrochemical biosensor.

Damage to DNA frequently involves interruption of DNA sugar-phosphate strands (strand breaks, sb). Under aerobic conditions, transition metal ions cause DNA damage through production of reactive oxygen species (frequently via Fenton-type reactions). Formation of sb in covalently closed supercoiled (sc) DNA can be detected using an electrochemical biosensor based on a scDNA-modified mercury electrode. By controlling the potential of the electrode, this technique can be employed in studies of redox reactions involved in formation of DNA strand breaks, and to detect species involved in these reactions. ScDNA anchored at HMDE was cleaved by catalytic amounts of iron/EDTA ions in the absence of chemical reductants when appropriate electrode potential (sufficiently negative to reduce [Fe(EDTA)]- to [Fe(EDTA)]2-) was applied. The process required oxygen or hydrogen peroxide. The extent of DNA damage increased with the shift of the electrode potential to negative values, displaying a sharp inflection point matching the potential of [Fe(EDTA)]2-/[Fe(EDTA)]- redox pair. In the absence of transition metal ions, significant DNA damage was observed at potentials sufficiently negative for reduction of dioxygen at the mercury electrode. This observation suggests cleavage of the surface-attached scDNA by radical intermediates of oxygen reduction at HMDE.

Effects of Oxidation Agents and Metal Ions on Binding of p53 to Supercoiled DNA.

Summary Wild type human full length (f.1.) tumor suppressor p53 protein binds preferentially to super-coiled (sc) DNA in vitro both in the presence and absence of the p53 consensus sequence (p53CON). This binding produces a ladder of retarded bands on the agarose gel. Bands revealed by immunoblotting with antibody DO-1 corresponded to the ethidium stained retarded bands. The intensity and the number of bands of p53-scDNA complex were decreased by physiological concentrations of unchelated zinc ions. Nickel and cobalt ions inhibited binding of p53 to scDNA and to p53CON in linear DNA fragments less efficiently than zinc. Compared to the intrinsic zinc strongly bound to Cys 176, Cys 238, Cys 242 and His 179 in the p53 core domain, binding of additional Zn(2+) to p53 was much weaker as shown by an easy removal of the latter ions by low concentrations of EDTA. Oxidation of the protein with diamide resulted in a decrease of the number of the retarded bands. Under the same conditions, no binding of oxidized p53 to p53CON in a linear DNA fragment was observed. In agreement with the literature oxidation of f.1. p53 with diamide was irreversible and was not reverted by an excess of DTT. We showed that in the presence of 0.1 mM zinc ions, oxidation of p53 became reversible. Other divalent cations tested (cadmium, cobalt, nickel) exhibited no such effect. We suggested that the irreversibility of p53 oxidation was due, at least in part, to the removal of intrinsic zinc from its position in the DNA binding domain (after oxidation of the three cysteines to which the zinc ion is coordinated in the reduced protein) accompanied by a change in the p53 conformation. Binding of C-terminal anti-p53 antibody also protected bacterially expressed protein against irreversible loss of activity due to diamide oxidation. Binding the human p53 core domain (segment 94-312) to scDNA greatly differed from that observed with the full-length p53. The core domain did not posses the ability to bind strongly to many sites in scDNA regardless of the presence or absence of p53CON suggesting involvement of some other domain (probably C-terminal) in binding of the full-length p53 to scDNA. Supershift experiments using antibodies against p53 N- or C-terminus suggested that in oxidized p53, scDNA binding through the C-terminus gained importance.

DNA bending due to specific p53 and p53 core domain-DNA interactions visualized by electron microscopy.

We have used transmission electron microscopy to analyze the specificity and the extent of DNA bending upon binding of full-length wild-type human tumor suppressor protein p53 (p53) and the p53 core domain (p53CD) encoding amino acid residues 94-312, to linear double-stranded DNA bearing the consensus sequence 5'-AGACATGCCTAGACATGCCT-3' (p53CON). Both proteins interacted with high specificity and efficiency with the recognition sequence in the presence of 50 mM KCl at low temperature ( approximately 4 degrees C) while the p53CD also exhibits a strong and specific interaction at physiological temperature. Specific complex formation did not result in an apparent reduction of the DNA contour length. The interaction of p53 and the p53CD with p53CON induced a noticeable salt-dependent bending of the DNA axis. According to quantitative analysis with folded Gaussian distributions, the bending induced by p53 varied from approximately 40 degrees to 48 degrees upon decreasing of the KCl concentration from 50 mM to approximately 1 mM in the mounting buffer used for adsorption of the complexes to the carbon film surface. The p53CD bent DNA by 35-37 degrees for all salt concentrations used in the mounting buffer. The bending angle of the p53/DNA complex under low salt conditions showed a somewhat broader distribution (sigma approximately 39 degrees ) than at high salt concentration (sigma approximately 31 degrees ) or for p53CD (sigma approximately 24-27 degrees ). Together, these results demonstrate that the p53CD has a dominant role in complex formation and that the complexes formed both by p53 and p53CD under moderate salt conditions are similar. However, the dependence of the bending parameters on ambient conditions suggest that the segments flanking the p53CD contribute to complex formation as well. The problems associated with the analysis of bending angles in electron microscopy experiments are discussed.

Monoclonal antibody against DNA adducts with osmium structural probes.

Osmium tetroxide complexes with nitrogen ligands (Os,L) have been widely used as probes of the DNA structure. A monoclonal antibody OsBP7H8 against DNA adducts with Os,L was produced in mice. OsBP7H8 does not bind to proteins or total yeast RNA modified with Os,2,2'-bipyridine (bipy) nor to the unmodified nucleic acids and proteins. The antibody recognizes DNA modified with Os,bipy (DNA-Os,bipy) or with OsO4,1,10-phenanthroline (DNA-Os,phen) but it does not cross-react with oxidized DNA and with DNA adducts of osmium tetroxide complexes with other ligands (such as pyridine, TEMED and bathophenanthroline disulfonic acid). The affinity of OsBP7H8 to DNA-Os,phen is about five-fold higher as compared to DNA-Os,bipy. The antibody can be thus applied either for recognition of single-stranded and distorted regions in DNA (after DNA modification with Os,bipy) or for detection of both single-stranded and double-stranded DNAs (after DNA modification with Os,phen). A new simplified procedure for the dot-blot analysis is proposed, not requiring the purification of DNA-osmium adduct prior to its application to the membrane.

Effect of p53 protein redox states on binding to supercoiled and linear DNA.

The binding of p53 to its DNA consensus sequence is modulated by the redox state of the protein in vitro. We have shown previously that reduced wild-type p53 binds strongly to supercoiled DNA (scDNA) regardless of the presence or absence of p53CON. Here we compare the effects of oxidation of p53 by azodicarboxylic acid bis[dimethylamide] (diamide) and other agents on p53 binding to p53CON and to scDNA. Oxidation decreases the binding of p53 to scDNA; however, under conditions where binding to p53CON in a DNA fragment is completely abolished, some residual binding to scDNA is still observed. Increasing the concentration of oxidized p53 confers minimal changes in p53 binding to both scDNA and p53CON. Reduction of the oxidized protein by dithiothreitol neither restores its binding to DNA nor to p53CON in DNA fragments. In the presence of excess zinc ions, oxidation of p53 is, however, reversible. We conclude that the irreversibility of p53 oxidation is due, at least in part, to the removal of intrinsic zinc from its position in the DNA binding domain accompanied by a conformational change of the p53 molecule after oxidation of the three cysteines to which the zinc ion is coordinated in the reduced protein.

Real-time monitoring of enzymatic cleavage of nucleic acids using a quartz crystal microbalance.

The use of quartz crystal microbalance (QCM) for monitoring in situ the enzymatic cleavage of surface-confined nucleic acids by nucleases is described. Such real-time monitoring of mass changes associated with the enzymatic digestion indicates that the activity and specificity of nucleases is preserved at the gold surface, and can be used for manipulating surface-confined DNAs and RNAs. These observations indicate great promise for using QCM for elucidating the interactions of nucleic acids with enzymes, and for enhancing the power of hybridization biosensors.

Effect of transition metals on binding of p53 protein to supercoiled DNA and to consensus sequence in DNA fragments.

Recently we have shown that wild-type human p53 protein binds preferentially to supercoiled (sc) DNA in vitro in both the presence and absence of the p53 consensus sequence (p53CON). This binding produces a ladder of retarded bands on an agarose gel. Using immunoblotting with the antibody DO-1, we show that the bands obtained correspond to ethidium-stained DNA, suggesting that each band of the ladder contains a DNA-p53 complex. The intensity and the number of these hands are decreased by physiological concentrations of zinc ions. At higher zinc concentrations, binding of p53 to scDNA is completely inhibited. The binding of additional zinc ions to p53 appears much weaker than the binding of the intrinsic zinc ion in the DNA binding site of the core domain. In contrast to previously published data suggesting that 100 microM zinc ions do not influence p53 binding to p53CON in a DNA oligonucleotide, we show that 5-20 microM zinc efficiently inhibits binding of p53 to p53CON in DNA fragments. We also show that relatively low concentrations of dithiothreitol but not of 2-mercaptoethanol decrease the concentration of free zinc ions, thereby preventing their inhibitory effect on binding of p53 to DNA. Nickel and cobalt ions inhibit binding of p53 to scDNA and to its consensus sequence in linear DNA fragments less efficiently than zinc; cobalt ions are least efficient, requiring >100 microM Co2+ for full inhibition of p53 binding. Modulation of binding of p53 to DNA by physiological concentrations of zinc might represent a novel pathway that regulates p53 activity in vivo.

Interactions of surface-confined DNA with acid-activated mitomycin C.

The anti-cancer drug mitomycin C (MC) was acid-activated and its interaction with single-stranded calf thymus DNA, immobilized at the surface of the hanging mercury drop electrode (DNA-modified HMDE) was studied by cyclic voltammetry. It was found that immersion of the DNA-modified electrode in a solution of acid-activated MC (at pH 3.9) for a short time (usually 1 min) at open current circuit, followed by transfer of the electrode in a neutral blank background electrolyte, resulted in a decrease of the anodic peak G (due to guanine residues in DNA) and in the formation of a reversible couple at approx. -0.44 V. The potential of the cathodic peak was approx. 50 mV more negative than the cathodic peak of the acid-activated MC obtained under the same conditions in the absence of DNA. No changes of peak G occurred and only a very small cathodic peak appeared if the DNA-modified electrode was immersed in an MC solution not exposed to acid pH. On the basis of these results and additional experiments, including dependence on concentration, time and pH during the interaction of MC with DNA at the electrode surface, we concluded that acid-activated MC is covalently bound to guanine residues in DNA immobilized at the electrode surface and that the quinone group in the DNA-MC adduct is reversibly reduced at the electrode.

Electrochemical biosensors for DNA hybridization and DNA damage.

Recent trends in the development of DNA biosensors for nucleotide sequence-specific DNA hybridization and for the detection of the DNA damage are briefly reviewed. Changes in the redox signals of base residues in DNA immobilized at the surface of carbon or mercury electrodes can be used as a sign of the damage of DNA bases. Some compounds interacting with DNA can produce their own redox signals on binding to DNA. Covalently closed circular (usually supercoiled) DNA attached to the electrode surface can be used for a sensitive detection of a single break of the DNA sugar-phosphate backbone and for detection of agents cleaving the DNA backbone such as hydroxyl radicals, ionizing radiation, nucleases, etc. Using the peptide nucleic acid in the biosensor recognition layer greatly increased the specificity of the DNA hybridization biosensor making it possible to detect point mutations (single-base mismatches) in DNA.

Analysis of a curved DNA constructed from alternating dAn:dTn-tracts in linear and supercoiled form by high resolution chemical probing.

Complex of osmium tetroxide and bipyridine (Os,bipy), KMnO4, and diethyl pyrocarbonate (DEPC) were used to probe curved DNA at single nucleotide resolution. The DNA was constructed from repeated dAn:dTn-blocks with dATATA and dAGAGA interblock sequences. The DNA was probed in the linear and supercoiled form at various salt concentrations. While all purines were available for DEPC attack, the thymines within the blocks were resistant to chemical probing by KMnO4 and Os,bipy. Only the 3'-flanking dTs were available for modification. The thymines within dTC and dTA sequences showed modification indicating that these thymines display an unstacked structure allowing both probes to attack. Under destabilizing conditions, at low ionic strength and superhelical stress, considerable unstacking was observed. We found experimental indications that under these destabilizing conditions unpaired regions might appear, probably within the dATATA sequence.

Two superhelix density-dependent DNA transitions detected by changes in DNA adsorption/desorption behavior.

The adsorption behavior of covalently closed circular plasmid DNA at the mercury/water interface was studied by means of AC impedance measurements. The dependence of the differential capacitance (C) of the electrode double layer on the potential (E) was measured in the presence of adsorbed DNA. It was found that the C-E curves of supercoiled DNA at native and highly negative superhelix densities (sigma), relaxed covalently closed circular DNA, and nicked DNA differed from each other. A detailed study of topoisomer distributions ranging from -sigma of 0 to 0.11 revealed two supercoiling-dependent transitions, at about -sigma = 0.04 (transition TI) and 0.07 (transition TII). Transition TI was detected by measuring the height of the adsorption/desorption peak 1 (at about -1.2 V against the saturated calomel electrode) and the decrease of capacitance (DeltaC) at -0.35 V. This transition may be due to a sudden change in the ability of the DNA to respond to the alternating voltage, probably caused by changes in the DNA tertiary and/or secondary structure. Transition TII was detected by measuring peak 3* (at about -1.3 V), which was absent in topoisomers with -sigma less than 0.05. This transition is due to changes in the DNA adsorption/desorption behavior related to increased accessibility of bases at elevated negative superhelix density. Opening of the duplex at highly negative superhelix density was also detected by the single-strand selective probe of DNA structure, osmium tetroxide, 2, 2'-bipyridine. Our results suggest that electrochemical techniques provide sensitive experimental analysis of changes in DNA structure.

A supercoiled DNA-modified mercury electrode-based biosensor for the detection of DNA strand cleaving agents.

DNA-damaging agents in the environment represent a serious danger to human health. We use a supercoiled DNA-modified mercury electrode as a fast-response biosensor for the detection of DNA strand cleaving agents. The sensor is based on a strong difference between the a.c. voltammetric responses of covalently closed circular (supercoiled) and of open circular (nicked) plasmid DNA. We show that the sensor can detect hydroxyl radicals in laboratory-prepared solutions and in various natural and industrial water samples. The sensor is also capable of detecting unknown DNA-damaging agents in industrial waters.