Influence of the SPR Experimental Conditions on the G-Quadruplex DNA Recognition by Porphyrin Derivatives.

Surface plasmon resonance (SPR) is a powerful technique to study the interactions of ligands with analytes and therefore a number of biosensor surfaces and injection methods have been developed so far. However, many experimental parameters can affect the interactions and consequently the affinity measurements. In particular, the interactions of positively charged analytes (often used for anionic nucleic acids targets) can be influenced by the sensing surfaces (e.g., negatively charged), leading to significant nonspecific interactions as well as regeneration problems. The aim of the present work is to investigate the effect of different parameters, including ionic strength, SPR biosensor (i.e., nature of the surfaces), and the injection method on the recognition of porphyrin G-quadruplex ligands. We demonstrate that the injection method does not influence the affinity whereas the ionic strength and the nature of the surface impact the recognition properties of the porphyrin for the G-quadruplex DNA. We also found that self-assembled monolayer coating surface presents many advantages in comparison with carboxymethylated dextran surface for SPR studies of G-quadruplex DNA/ligand interactions: (i) the electrostatic interaction with charged analytes is less important, (ii) its structure/composition is less sensitive to the ionic concentration and less prone to unspecific adsorption, (iii) it is easily homemade, and (iv) the cost is approximately 10 times cheaper.

Isoniazid: an update on the multiple mechanisms for a singular action.

Isoniazid (INH) is one of the most commonly used drugs in treatment of human tuberculosis and the most efficient. Although it has been 60 years since isoniazid was introduced in anti-tubercular therapy and despite the simplicity of its chemical structure (C6H7N3O) with few functional groups, its exact mechanism of action, which could account for its specificity and exceptional potency against Mycobacterium tuberculosis and justify all profiles of INH-resistance, remains elusive and debatable. This complexity can find an explanation in the high reactivity of INH and also in the possibility that multiple targets and pathways could co-exist for this medicinal agent. Indeed, since the discovery of isoniazid's anti-tubercular potency, several propositions for its mode of action have been reported, including its conversion, by a catalase peroxidase within M. tuberculosis, into an active metabolite able, after reaction with NAD, to inhibit an enzyme (InhA) crucial to M. tuberculosis survival. This represents the most consensual mechanism described to date. Nevertheless, none of the proposed mechanisms considered independently can explain the singular and privileged action of the isoniazid structure on the tubercle bacillus, or all the profiles of resistance. The aim of this paper is to reconsider the literature reporting the different modes of action described for isoniazid in the light of the present and most relevant knowledge, with special attention to understanding the molecular mechanistic aspects of the drug's action.

Comparison of the cleavage profiles of oligonucleotide duplexes with or without phosphorothioate linkages by using a chemical nuclease probe.

A manganese porphyrin complex, Mn-TMPyP, associated with KHSO(5) is a chemical nuclease able to selectively recognize the minor groove of three consecutive AT base pairs of DNA and to mediate very precise cleavage chemistry at that particular site. This specific recognition and cleavage were used to probe the accessibility of the minor groove of DNA duplexes composed of one phosphodiester strand and one phosphorothioate strand. The cleavage of 5'-GCAAAAGC/5'-GCTTTTGC duplexes by Mn-TMPyP/KHSO(5) was monitored by HPLC coupled to electrospray mass analysis. Each single strand was synthesized with all-phosphate, all- Rp-phosphorothioate and all- Sp-phosphorothioate internucleotide bonds. We found that the manganese porphyrin was able to recognize its favorite (AT)(3)-box binding site within the heteroduplexes, as in the case of natural DNA. Molecular modeling studies on the interactions of the reactive porphyrin manganese-oxo species with both types of duplexes confirmed the experimental data.

Characterization of a 5'-aldehyde terminus resulting from the oxidative attack at C5' of a 2-deoxyribose on DNA.

The 5'-aldehyde terminus is a DNA oxidative damage resulting from attack at C5' of 2-deoxyriboses by some potent natural or chemical DNA cleavers. To offer a fast and specific method for characterization of this type of damage, we used on-line electrospray ionization mass spectrometry (ESI-MS) detection during liquid chromatography analyses. The intrinsic reactivity of 5'-aldehyde terminus with nucleophiles (formation of hydrate with water, of a Tris adduct with Tris buffer) or through beta-elimination reaction resulted in complex LC profiles and MS data. We showed that derivatization of the aldehyde function as an oxime ether gives a stable derivative easy to characterize during on-line ESI-MS analyses. Complete structural characterization of the Tris adduct and the oxime ether derivative were obtained from MS and detailed NMR studies performed on derivatized 5'-aldehyde thymidine models.

Convenient method for the preparation of 2'-deoxyribosylurea by thymidine oxidation and NMR study of both anomers.

The synthesis of 2'-deoxyribosylurea by thymidine oxidation with potassium permanganate followed by alkaline hydrolysis of intermediates is described. The anomeric configuration of the resulting products was studied by NMR spectroscopy.

Guanine oxidation: NMR characterization of a dehydro-guanidinohydantoin residue generated by a 2e-oxidation of d(GpT).

The Mn-TMPyP/KHSO(5) system was used to oxidize guanine contained within a dinucleoside monophosphate d(GpT). To identify the guanine oxidation product having a mass with 4 amu above the mass of guanine itself, this relatively unstable compound was reduced to a more stable one. The ESI/MS and NMR data allowed us to propose a dehydro-guanidinohydantoin structure for the (G+4) guanine oxidation product.

Guanine Oxidation in Double-stranded DNA by MnTMPyP/KHSO(5): At Least Three Independent Reaction Pathways.

In order to better define the mechanism and the products of guanine oxidation within DNA, we investigated the details of the mechanism of guanine oxidation by a metalloporphyrin, Mn-TMPyP, associated to KHSO(5) on oligonucleotides. We found that the three major products of guanine oxidation are formed by independent reaction routes. The oxidized guanidinohydantoin (1) and the proposed spiro compound 3 derivatives are not precursors of imidazolone lesion (Iz). These guanine lesions as well as their degradation products, may account for non-detected guanine oxidation products on oxidatively damaged DNA.

Characterization of an oxaluric acid derivative as a guanine oxidation product.

The oxidation of guanine in the dinucleoside monophosphate d(GpT) by an oxo-metalloporphyrin generates a linear oxaluric acid derivative after heating at 65 degrees C for 30 min and at neutral pH.

Oxidative damage generated by an oxo-metalloporphyrin onto the human telomeric sequence.

The cationic metalloporphyrin Mn-TMPyP activated by KHSO(5) has been used as cleaver of an oligonucleotide containing the four human telomere repeats of 5'-GGGTTA. This oligonucleotide formed an intramolecular quadruplex DNA under 200 mM KCl as probed by DMS footprinting and could fold into different quadruplex structures under 200 mM NaCl. We found that the oxo-metalloporphyrin was able to mediate efficient oxidative cleavage of the quadruplex. The location of damage showed that the metalloporphyrin was able to bind to the last G-tetrad of the quadruplex structure via an external interaction. This metalloporphyrin-G-tetrad interaction needs a relatively high flexibility of the single-stranded linker regions to allow the partial stacking of the metalloporphyrin with the last G-tetrad planar structure. The oxidative damage consisted of guanine oxidation within the interacting G-tetrad together with an 1'-carbon hydroxylation of deoxyribose residues of the thymidine residues located on the neighboring single-stranded loop. So the high-valent oxo-metalloporphyrin is able to mediate both electron-abstraction or H-abstraction on G or T residues, respectively, within the DNA quadruplex target.

Modification of the thiourea linkage of a fluorescein-oligonucleotide conjugate to a guanidinium motif during ammonia deprotection.

During the preparation of a fluorescent conjugate based on a manganese cationic porphyrin carboxylate derivative linked to a 5'-amino-3'-fluorescein-labeled oligonucleotide, we observed the chemical transformation of the thiourea linkage to a guanidinium function during the deprotection in ammonia of the 3'-fluorescein-oligonucleotide from CPG support. We also noted a secondary reactivity of the activated carboxylate group of the metalloporphyrin precursor with the fluorescein entity of the conjugated oligonucleotide.

Influence of the nature of the porphyrin ligand on the nuclease activity of metalloporphyrin-oligonucleotide conjugates designed with cationic, hydrophobic or anionic metalloporphyrins.

The synthesis of metalloporphyrin-oligonucleotide conjugates with different metalloporphyrin moieties are described as well as the comparison of their in vitro nuclease efficiency toward a single-stranded DNA target. Between cationic, anionic and hydrophobic manganese porphyrins covalently linked to the oligonucleotide, the best nuclease activity was obtained with the cationic ones, suggesting that the affinity of the cleaver to the DNA target is a key factor.

Structure/nuclease activity relationships of DNA cleavers based on cationic metalloporphyrin-oligonucleotide conjugates.

The covalent attachment of a managanese-tris(methylpyridiniumyl)porphyrin entity to an antisense oligonucleotide allowed sequence-selective oxidative cleavage of DNA when the metalloporphyrin was activated by potassium monopersulfate (KHSO5). We prepared several structurally modified metallo-porphyrin-oligonucleotide conjugates in order to find out the most efficient compound for in vitro DNA cleavage. The nature and the length of the tether were modulated, the metalloporphyrin entity was modified (metal, ligand), and different ways of activation of the metalloporphyrin were assayed. We noticed that the location of the peptidic bond within the linker could greatly affect the cleavage efficiency of the different conjugates. We showed that the most efficient conjugate for oxidative DNA cleavage was a manganese tetracationic porphyrin-oligonucleotide compound. When the metalloporphyrin moiety was activated by a reducing agent in the presence of molecular oxygen, DNA cleavage was efficient at suitable concentrations of the reducing agent, in order to avoid the reduction of the activated DNA cleaver, a putative high-valent metal-oxo species, by the excess of reducing agent.

Cleavage of double-stranded DNA by 'metalloporphyrin-linker-oligonucleotide' molecules: influence of the linker.

Manganese porphyrin-linker-triple-helix-forming oligonucleotide molecules were prepared and their ability to cleave in vitro a double-stranded DNA target present in the HIV-1 genome was studied. The nature of the linker is a determining factor of the cleavage efficiency. Cleavage yields as high as 80% were observed when the linker was a spermine residue and in the absence of a large excess of free spermine known to stabilize triplex structures. The hydrophobic nature of aliphatic diamine linker modified the cleaver-DNA interactions and reduced the efficiency of DNA cleavage.

Preparation and nuclease activity of hybrid "metallotris(methylpyridinium)porphyrin oligonucleotide" molecules having a 3'-loop for protection against 3'-exonucleases.

A 5'-GCGAAAGC minihairpin structure was added to the 3'-end of an oligonucleotide substituted at the 5'-end by a manganese cationic porphyrin in order to enhance the 3'-exonuclease resistance of these cleaver-antisense molecules. The influence of this minihairpin on the 3'-exonuclease resistance, the binding affinity to a target ssDNA, and the cleaving efficiency of Mn-cationic porphyrin oligonucleotide conjugates was compared to that of the parent molecule without the 3'-hairpin. The results showed that the 3'-hairpin slightly decreased the binding affinity and consequently the cleaving efficiency of the conjugated molecule toward a target sequence, but the much higher nuclease resistance makes 3'-minihairpin-protected metalloporphyrin oligonucleotides good candidates as reactive antisense oligonucleotides for studies on cells.

Preferential hydroxylation by the chemical nuclease meso-tetrakis-(4-N-methylpyridiniumyl)porphyrinatomanganeseIII pentaacetate/KHSO5 at the 5' carbon of deoxyriboses on both 3' sides of three contiguous A.T base pairs in short double-stranded oligonucleotides.

Selected double-stranded oligodeoxyribonucleotides have been used to probe, at the molecular level, DNA chain breakages induced by the chemical nuclease mesotetrakis(4-N- methylpyridiniumyl)porphyrinatomanganeseIII pentaacetate/KHSO5. The results show that cleavage selectively occurs on the two 3' sides of three contiguous A.T base pairs (an A.T triplet). Hydroxylation at 5' carbon of the deoxyribose targets represents the initial damage on the sugar-phosphodiester backbone and leaves a 3' phosphate and a 5' aldehyde at the ends. The fragments were separated by HPLC and unambiguously identified through chemical and biochemical reactions and/or sequencing after enzymatic conversion to mononucleosides. Also studied was the degradation of a 22-nucleotide DNA molecule containing two A.T triplets. Gel electrophoresis analyses on the corresponding 5'-32P-end-labeled substrate supported the above cleavage specificity and mechanism.

Mechanism of DNA cleavage by cationic manganese porphyrins: hydroxylations at the 1'-carbon and 5'-carbon atoms of deoxyriboses as initial damages.

Cationic manganese-porphyrin complexes, free or targetted with an intercalating agent, are able to cleave DNA using oxygen atom donors like potassium monopersulfate or magnesium monoperphthalate as coreactants. Detailed studies of the cleavage of calf thymus DNA, before and after a heating step, show that free bases and 5-methylene-2-furanone are the main reaction products, indicating that hydroxylation at the 1'-carbon atom is the main target of these chemical agents. These data confirm that metalloporphyrin derivatives interact with the minor groove of double-stranded DNA. Hydroxylation of one of the two C-H bonds at position-5' is another initial DNA damage, characterized by the formation of furfural as sugar degradation product. Besides these two main initial damage sites, a low contribution of a hydroxylation reaction at C4' can not be definitively discounted, while an hydroperoxidation route at C4' can be excluded.

31P NMR characterization of terminal phosphates induced on DNA by the artificial nuclease 'Mn-TMPyP/KHSO5' in comparison with DNases I and II.

Phosphorus-31 NMR has been applied to the characterization of terminal phosphates on fragments of calf thymus DNA induced by three different nuclease systems: DNase I, DNase II and the artificial nuclease 'Mn-TMPyP/KHSO5'. In this last case, the oxidative damage to deoxyribose leads to two monophosphates esters (at the 3' and 5' ends) on both sides of the cleavage site. This method constitutes a promising approach to visualise the phosphate termini generated in DNA or RNA cleavage by cytotoxic drugs or chemical nucleases and provides a novel insight into the molecular aspects of their mechanism of action.

Cytotoxic and DNA-damaging effects of 1,2-bis(sulfonyl)hydrazines on human cells of the Mer+ and Mer- phenotype.

A series of 1,2-bis(sulfonyl)hydrazines with the capacity to function as alkylating agents have been evaluated for their toxicity towards Mer- HT29 and Mer- BE cells, and for their ability to produce DNA damage expressed as single-strand breaks and DNA interstrand cross-links. Compounds of this class with methylating potential showed a marked difference in their capacity to inhibit the growth of Mer- and Mer+ cells, being considerably more toxic to BE Mer- cells. Dose-dependent DNA single-strand breaks were induced by these agents, with the quantity of breaks produced in Mer- and Mer+ cells being essentially the same. Maintenance of these lesions did not appear to explain the differential in toxicity to BE and HT29 cells. A chloroethylating compound of this class was also more toxic to Mer- BE cells than to Mer+ HT29 cells, but the differential toxicity was considerably less than that of the methylating agents of the series. The chloroethylating agent did not produce measurable single-strand breaks of the DNA of treated cells, but caused more DNA interstrand cross-links in Mer- cells than in Mer+ cells. Thus, DNA interstrand cross-links may be at least in part responsible for the cell kill produced by this agent. The findings suggest that methylating and chloroethylating derivatives of the 1,2-bis(sulfonyl)hydrazine family have different biochemical determinants of their cytodestructive actions.

Potassium monopersulfate and a water-soluble manganese porphyrin complex, [Mn(TMPyP)](OAc)5, as an efficient reagent for the oxidative cleavage of DNA.

Reported studies indicate that the association of potassium monopersulfate with [Mn(TMPyP)](OAc)5, a water-soluble manganese porphyrin complex, leads to an efficient reagent for the oxidative cleavage of DNA. Single-strand breaks (SSBs) are observed on double-stranded DNA at manganese porphyrin concentrations as low as 0.5 nM with a short incubation time of 1 min. The number of SSBs linearly varies with the concentration of the manganese complex, and potassium monopersulfate is at least 3 orders of magnitude more efficient as oxygen source than hydrogen peroxide. Cleavage efficiency is optimal in the pH range 7.5-9.0 for a NaCl concentration between 80 and 150 mM or for a MgCl2 concentration of 10 mM. At very low manganese porphyrin concentration and by increasing the incubation time a catalytic cleavage activity of the complex is evidenced: up to 5 SSBs per manganese porphyrin are observed. The high cleavage activity of the monopersulfate-manganese porphyrin system makes it a good candidate for DNA-footprinting experiments.