Reconfigurable Implication and Inhibition Boolean logic gates based on NAD+-dependent enzymes: Application to signal-controlled biofuel cells and molecule release

AbstractThe Implication and Inhibition Boolean logic gates were realized using NAD+/NADH‐dependent dehydrogenases combined with hexokinase competing for biomolecule input signals. Both logic gates operated with the same enzyme composition and their reconfiguration was achieved simply by redefining the input signals. The output signals produced by the logic gates were analyzed optically and electrochemically, particularly using enzyme‐modified electrodes. The logically processed input signals were used to switch operation of a biofuel cell and activate a molecule release process

Pyrimidine Ribonucleotides with Enhanced Selectivity as P2Y 6 Receptor Agonists: Novel 4-Alkyloxyimino, (S)-Methanocarba, and 5′-Triphosphate γ-Ester Modifications †

The P2Y6 receptor is a cytoprotective G protein-coupled receptor (GPCR) activated by UDP (EC50, 0.30 μM). We compared and combined modifications to enhance P2Y6 receptor agonist selectivity, including ribose ring constraint, 5-iodo and 4-alkyloxyimino modifications, and phosphate modifications such as α,β-methylene and extension of the terminal phosphate group into γ-esters of UTP analogues. The conformationally constrained (S)-methanocarba UDP is a full agonist (EC50 0.042 μM). 4-Methoxyimino modification of pyrimidine enhanced P2Y6, preserved P2Y2 and P2Y4, and abolished P2Y14 receptor potency, in the appropriate nucleotide. N4-Benzyloxy-CDP (15, MRS2964) and N4-methoxy-Cp3U (23, MRS2957) were potent, selective P2Y6 receptor agonists (EC50 0.026 μM and 0.012 μM, respectively). A hydrophobic binding region near the nucleobase was explored with receptor modeling and docking. UTP-γ-aryl and cycloalkyl phosphoesters displayed only intermediate P2Y6 receptor potency, but had enhanced stability in acid and cell membranes. UTP-glucose was inactive, but its (S)-methanocarba analogue and N4-methoxy-cytidine 5′-triphospho-γ-[1]glucose were active (EC50 of 2.47 μM and 0.18 μM, respectively). Thus, the potency, selectivity, and stability of pyrimidine nucleotides as P2Y6 receptor agonists may be enhanced by modest structural changes

Molecular recognition in the P2Y14 receptor: Probing the structurally permissive terminal sugar moiety of uridine-5′-diphosphoglucose

The P2Y14 receptor, a nucleotide signaling protein, is activated by uridine-5′-diphosphoglucose 1 and other uracil nucleotides. We have determined that the glucose moiety of 1 is the most structurally permissive region for designing analogues of this P2Y14 agonist. For example, the carboxylate group of uridine-5′-diphosphoglucuronic acid proved to be suitable for flexible substitution by chain extension through an amide linkage. Functionalized congeners containing terminal 2-acylaminoethylamides prepared by this stratgegy retained P2Y14 activity, and molecular modeling predicted close proximity of this chain to the 2nd extracellular loop of the receptor. In addition, replacement of glucose with other sugars did not diminish P2Y14 potency. For example, the [5″]ribose derivative had an EC50 of 0.24 μM. Selective monofluorination of the glucose moiety indicated a role for the 2″- and 6″-hydroxyl groups of 1 in receptor recognition. The β-glucoside was 2-fold less potent than the native α-isomer, but methylene replacement of the 1″-oxygen abolished activity. Replacement of the ribose ring system with cyclopentyl or rigid bicyclo[3.1.0]hexane groups abolished activity. Uridine-5′-diphosphoglucose also activates the P2Y2 receptor, but the 2-thio analogue and several of the potent modified-glucose analogues were P2Y14-selective

Reductive Mobilization of Iron from Intact Ferritin: Mechanisms and Physiological Implication

Ferritins are highly conserved supramolecular protein nanostructures composed of two different subunit types, H (heavy) and L (light). The two subunits co-assemble into a 24-subunit heteropolymer, with tissue specific distributions, to form shell-like protein structures within which thousands of iron atoms are stored as a soluble inorganic ferric iron core. In-vitro (or in cell free systems), the mechanisms of iron(II) oxidation and formation of the mineral core have been extensively investigated, although it is still unclear how iron is loaded into the protein in-vivo. In contrast, there is a wide spread belief that the major pathway of iron mobilization from ferritin involves a lysosomal proteolytic degradation of ferritin, and the dissolution of the iron mineral core. However, it is still unclear whether other auxiliary iron mobilization mechanisms, involving physiological reducing agents and/or cellular reductases, contribute to the release of iron from ferritin. In vitro iron mobilization from ferritin can be achieved using different reducing agents, capable of easily reducing the ferritin iron core, to produce soluble ferrous ions that are subsequently chelated by strong iron(II)-chelating agents. Here, we review our current understanding of iron mobilization from ferritin by various reducing agents, and report on recent results from our laboratory, in support of a mechanism that involves a one-electron transfer through the protein shell to the iron mineral core. The physiological significance of the iron reductive mobilization from ferritin by the non-enzymatic FMN/NAD(P)H system is also discussed

Operando Local pH Mapping of Electrochemical and Bioelectrochemical Reactions Occurring at an Electrode Surface: Effect of the Buffer Concentration

In this study, we aim at demonstrating the possibility for operando quantification of the thickness of the boundary layer where pH changes are occurring upon electrochemical reactions accompanied with the production or consumption of H+ cations. Confocal fluorescent microscopy (CFM) is combined with two different pH sensitive fluorescent dyes, namely 3,4 '-dihydroxy-3 ',5 '-bis-(dimethylaminomethyl)flavone (FAM345) and rhodamine-6-aniline (R6H). This is the first attempt to quantify the effect of the buffer concentration (quantification of layer thickness) on local pH changes produced by ascorbic oxidation and oxygen reduction reaction directly occurring at non-modified graphite electrodes. In addition, the effect of buffer concentration was studied also with respect to local pH variations produced by bioelectrochemical reactions

Photodegradable Iron(III) Cross-Linked Alginate Gels

Biocompatible photoresponsive materials are of interest for targeted drug delivery, tissue engineering, 2D and 3D protein patterning, and other biomedical applications. We prepared light degradable hydrogels using a natural alginate polysaccharide cross-linked with iron­(III) cations. The “hard” iron­(III) cations used to cross-link the alginate hydrogel were found to undergo facile photoreduction to “soft” iron­(II) cations in the presence of millimolar concentrations of sodium lactate. The “soft” iron­(II) cations have a decreased ability to cross-link the alginate which results in dissolution of the hydrogel and the formation of a homogeneous solution. The photodegradation is done using long wave UV or visible light at neutral pH. The very mild conditions required for the photodegradation and the high rate at which it occurs suggest applications for iron­(III) cross-linked alginate hydrogels as light-controlled biocompatible scaffolds

Boolean Logic Networks Mimicked with Chimeric Enzymes Activated/Inhibited by Several Input Signals

Reactions catalyzed by artificial allosteric enzymes, chimeric proteins with fused biorecognition and catalytic units, were used to mimic multi-input Boolean logic systems. The catalytic parts of the systems were represented by pyrroloquinoline quinone-dependent glucose dehydrogenase (PQQ-GDH). Two biorecognition units, calmodulin or artificial peptide-clamp, were integrated into PQQ-GDH and locked it in the OFF or ON state respectively. The ligand-peptide binding cooperatively with Ca2+ cations to a calmodulin bioreceptor resulted in the enzyme activation, while another ligand-peptide bound to a clamp-receptor inhibited the enzyme. The enzyme activation and inhibition originated from peptide-induced allosteric transitions in the receptor units that propagated to the catalytic domain. While most of enzymes used to mimic Boolean logic gates operate with two inputs (substrate and co-substrate), the used chimeric enzymes were controlled by four inputs (glucose – substrate, dichlorophenolindophenol – electron acceptor/co-substrate, Ca2+ cations and a peptide – activating/inhibiting signals). The biocatalytic reactions controlled by four input signals were considered as logic networks composed of several concatenated logic gates. The developed approach allows potentially programming complex logic networks operating with various biomolecular inputs representing potential utility for different biomedical applications.</p