Nitric oxide triggered dephosphorylation reactions

Enemchukwu, Emeka Martin

01 1900

The synergistic effect of nitric oxide toward dephosphorylation reactions involving phosphate esters was the subject of investigation in this research. Sodium nitroprusside under UV irradiations at 254nm, 365nm and white light was utilized as nitric oxide donor in solutions. The effects of cobalt trimethylenediamine and nitroprusside towards dephosphorylation of nitrophenylphosphate and pyrophosphate which were modeled as organophosphate ester substrates were also investigated. The activated substrate models showed more rate enhancement than the unactivated models in all cases. The direct interaction of nitric oxide with the phosphorus centre is presumed to be the reason for enhanced hydrolysis. This study demonstrates the possible role of nitric oxide in decontamination reactions of poorly biodegradable phosphate esters in the biosphere. / Chemistry / M. Sc. (Chemistry)

Nitric oxide

Nitrophenylphosphate

Sodium nitroprusside

Dephosphorylation

Phototransformation

Decontamination

Inorganic phosphate

Inorganic pyrophosphate

Nitrophenolate ion

Trimethylenediamine

Organophosphate esters

Ultra violet radiation

541.39

Nitric oxide

Phosphate esters

Ultraviolet radiation

Nitric oxide triggered dephosphorylation reactions

Enemchukwu, Emeka Martin

01 1900

The synergistic effect of nitric oxide toward dephosphorylation reactions involving phosphate esters was the subject of investigation in this research. Sodium nitroprusside under UV irradiations at 254nm, 365nm and white light was utilized as nitric oxide donor in solutions. The effects of cobalt trimethylenediamine and nitroprusside towards dephosphorylation of nitrophenylphosphate and pyrophosphate which were modeled as organophosphate ester substrates were also investigated. The activated substrate models showed more rate enhancement than the unactivated models in all cases. The direct interaction of nitric oxide with the phosphorus centre is presumed to be the reason for enhanced hydrolysis. This study demonstrates the possible role of nitric oxide in decontamination reactions of poorly biodegradable phosphate esters in the biosphere. / Chemistry / M. Sc. (Chemistry)

Nitric oxide

Nitrophenylphosphate

Sodium nitroprusside

Dephosphorylation

Phototransformation

Decontamination

Inorganic phosphate

Inorganic pyrophosphate

Nitrophenolate ion

Trimethylenediamine

Organophosphate esters

Ultra violet radiation

541.39

Nitric oxide

Phosphate esters

Ultraviolet radiation

Fabrication and use of new solid state phosphate ion selective electrodes for monitoring phosphorylation and dephosphorylation reactions

Enemchukwu, Emeka Martin

06 1900

Highly selective and sensitive phosphate sensors have been fabricated by constructing a solid membrane disk consisting of variable mixtures of aluminium powder (Al), aluminium phosphate (AlPO4) and powdered copper (Cu). Both binary and ternary electrode systems are produced depending on their composition. The ternary membranes exhibit greater selectivity over a wide range of concentrations. The ternary electrode with the composition 25% AlPO4, 25% Cu and 50% Al was selected as our preferred electrode. The newly fabricated ternary membrane phosphate selective electrodes exhibited linear potential response in the concentration range of 1.0 × 10−6 to 1.0 × 10−1 mol L−1. The electrodes also exhibit a fast response time of <60 s. Their detection limit is 1.0 × 10−6 mol L−1. The unique feature of the described electrodes is their ability to maintain a steady and reproducible response in the absence of an ionic strength control. The electrodes have a long lifetime and can be stored in air when not in use. The selectivity of the new phosphate selective electrodes with respect to other common ions is excellent. The results obtained provide further insight into the working principles of the newly fabricated phosphate selective electrodes. Dephosphorylation and phosphorylation reactions were monitored using the preferred phosphate selective electrode. The following reactions were studied and inferences drawn; (a) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[OH(PO2O)]2- for 1:1, 2:1 and 3:1 *[{CoN4(OH)(OH2)}]2+ to *[OH(PO2O)]2- ratios.(b) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[O2NC6H4PO2(O)(OH)]- for 1:1, 2:1 and 3:1 *[{CoN4(OH)(OH2)}]2+ to *[O2NC6H4PO2(O)(OH)]- ratios. (c) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[(OH)2(PO2)2O]2- for 1:1, 2:1 and 3:1 [{CoN4(OH)(OH2)}]2+ to *[(OH)2(PO2)2O]2- ratios, and (d) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[(OH)2(PO2)3O2]3- for the 1:1, 2:1 and 3:1 [{CoN4(OH)(OH2)}]2+ to *[(OH)2(PO2)3O2]3- ratios. Further insight into dephosphorylation and phosphorylation reactions is unravelled by the novel phosphate selective electrode monitoring. *For clarity of the complexes utilized, see chapter 4, table 4.1. KEY WORDS; Dephosphorylation, phosphorylation, ion selective electrodes, phosphate ion selective electrode, decontamination, electromotive force, potential difference, activity, concentration, selectivity coefficient, calibration, ionic strength, hydrolysis, inorganic phosphates, nitrophenylphosphate, pyrophosphate, tripolyphosphate, organophosphate esters. / Chemistry / D.Phil (Chemistry)

Dephosphorylation

Phosphorylation

Ion selective electrodes

Phosphate ion selective electrode

Decontamination

Electromotive force

Potential difference

Selectivity coefficient

Calibration

Ionic strength

Hydrolysis

Inorganic phosphates

Nitrophenylphosphate

Pyrophosphate

Tripolyphosphate

Organophosphate esters

541.39

Phosphate esters

Electrodes, Ion selective

Calibration

Phosphates

Solid state chemistry

L’entérotoxine STb d’Escherichia coli déloge la claudine-1 des jonctions serrées

Nassour, Hassan

04 1900

Escherichia coli produit diverses entérotoxines thermolabiles et thermostables. STb est une toxine de faible poids moléculaire résistant à la chaleur chargée de la diarrhée chez les animaux de la ferme. Une étude antérieure a montré que les cellules ayant internalisé la toxine STb provoquent un dysfonctionnement de la barrière épithéliale par des changements dans les protéines des jonctions serrées (TJ). Ces modifications contribuent probablement à la diarrhée observée. Pour mieux comprendre le mécanisme de l'augmentation de la perméabilité intestinale, nous avons traité les cellules du côlon humain (T84) avec la toxine purifiée STb une fois que les cellules ont été récoltées et les protéines extraites. Après l'utilisation d'une solution contenant 1% de Nonidet P-40 (un détergent non dénaturant, non ionique), nous avons étudié la distribution de la claudine -1, une protéine majeure des TJs, responsable de l'imperméabilité de l'épithélium, entre la membrane (NP40-insoluble) et le cytoplasme (NP40-soluble). En utilisant l’immunoblot et la microscopie confocale, nous avons observé que le traitement des monocouches de cellules T84 avec STb induit la redistribution de la claudine-1. Après 24h, les cellules cultivées en milieu faible en Ca+ (5 uM) et traitées par STb, ont montré qu’environ 40 % de plus de la claudine-1 se sont délogées dans le cytoplasme par comparaison au contrôle. En passant d’un milieu faible à un milieu contenant des quantités physiologiques de Ca++ (1,8 mM) nous avons observé une augmentation du taux de claudine- 1 délogé, comme la délocalisation comparable et ce, après 6h. Un milieu supplémenté avec la même concentration de Mg++ ou Zn++ n'a pas affecté le taux de délogement comparé au milieu contenant une faible teneur en Ca++. En utilisant des anticorps anti-phosphosérine et anti-phosphothréonine, nous avons observé que la perte des claudines-1 de la membrane a été accompagnée par une déphosphorylation de cette protéine des TJs. Dans l'ensemble, nos résultats ont montré une importante redistribution de la claudine-1 dans les cellules traitées par la toxine STb. La perte de la claudine-1 phosphorylée de la membrane est susceptible d'être impliquée dans la perméabilité accrue observée. Les mécanismes par lesquels ces changements sont provoqués restent à élucider. / Enterotoxigenic Escherichia coli produce various heat-labile and heat-stable enterotoxins. STb is a low molecular weight heat-resistant toxin responsible for diarrhea in farm animals. A previous study demonstrated that cells having internalized STb toxin induce epithelial barrier dysfunction through changes in tight junction (TJ) proteins. These modifications contribute probably to the diarrhea observed. To gain insight into the mechanism of increased intestinal permeability we treated human colon cells (T84) with purified STb toxin after which cells were harvested and proteins extracted. Using a 1% Nonidet P-40 (a non-ionic, non-denaturing detergent)-containing solution we investigated the distribution of claudin-1, a major TJ protein responsible for the epithelium impermeability, between membrane (NP40-insoluble) and the cytoplasmic (NP40- soluble) location. Using immunoblot and confocal microscopy, we observed that treatment of T84 cell monolayers with STb induced redistribution of claudin-1. After 24h, cells grown in low Ca++-containing medium (5 μM) treated with STb, showed about 40% more claudin-1 in the cytoplasm compare to the control. Switching from low to physiological Ca++-containing medium (1,8 mM) increased the dislodgement rate of claudin-1, as comparable delocalization was observed after 6h. Medium supplemented with the same concentration of Mg++ or Zn++ did not affect the dislodgement rate compare to the low Ca++-containing medium. Using anti- phosphoserine and anti-phosphothreonine antibodies we observed that the loss of membrane claudin-1 was accompanied by dephosphorylation of this TJ protein. Overall, our findings showed an important redistribution of claudin-1 in cells treated with STb toxin. The loss of phosphorylated TJ membrane claudin-1 is likely to be involved in the increased permeability observed. The mechanisms by which these changes are brought about remain to be elucidated.

Jonctions serrées

claudine-1

soluble

insoluble

diarrhée

phosphorylation/déphosphorylation

Escherichia coli

sécrétion

toxine STb

Tight junction

claudine-1

soluble

insoluble

diarrhea

phosphorylation/dephosphorylation

Escherichia coli

secretion

STb toxine

Fabrication and use of new solid state phosphate ion selective electrodes for monitoring phosphorylation and dephosphorylation reactions

Enemchukwu, Emeka Martin

06 1900

Highly selective and sensitive phosphate sensors have been fabricated by constructing a solid membrane disk consisting of variable mixtures of aluminium powder (Al), aluminium phosphate (AlPO4) and powdered copper (Cu). Both binary and ternary electrode systems are produced depending on their composition. The ternary membranes exhibit greater selectivity over a wide range of concentrations. The ternary electrode with the composition 25% AlPO4, 25% Cu and 50% Al was selected as our preferred electrode. The newly fabricated ternary membrane phosphate selective electrodes exhibited linear potential response in the concentration range of 1.0 × 10−6 to 1.0 × 10−1 mol L−1. The electrodes also exhibit a fast response time of <60 s. Their detection limit is 1.0 × 10−6 mol L−1. The unique feature of the described electrodes is their ability to maintain a steady and reproducible response in the absence of an ionic strength control. The electrodes have a long lifetime and can be stored in air when not in use. The selectivity of the new phosphate selective electrodes with respect to other common ions is excellent. The results obtained provide further insight into the working principles of the newly fabricated phosphate selective electrodes. Dephosphorylation and phosphorylation reactions were monitored using the preferred phosphate selective electrode. The following reactions were studied and inferences drawn; (a) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[OH(PO2O)]2- for 1:1, 2:1 and 3:1 *[{CoN4(OH)(OH2)}]2+ to *[OH(PO2O)]2- ratios.(b) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[O2NC6H4PO2(O)(OH)]- for 1:1, 2:1 and 3:1 *[{CoN4(OH)(OH2)}]2+ to *[O2NC6H4PO2(O)(OH)]- ratios. (c) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[(OH)2(PO2)2O]2- for 1:1, 2:1 and 3:1 [{CoN4(OH)(OH2)}]2+ to *[(OH)2(PO2)2O]2- ratios, and (d) the reactions between *[{CoN4(OH)(OH2)}]2+ and *[(OH)2(PO2)3O2]3- for the 1:1, 2:1 and 3:1 [{CoN4(OH)(OH2)}]2+ to *[(OH)2(PO2)3O2]3- ratios. Further insight into dephosphorylation and phosphorylation reactions is unravelled by the novel phosphate selective electrode monitoring. *For clarity of the complexes utilized, see chapter 4, table 4.1. KEY WORDS; Dephosphorylation, phosphorylation, ion selective electrodes, phosphate ion selective electrode, decontamination, electromotive force, potential difference, activity, concentration, selectivity coefficient, calibration, ionic strength, hydrolysis, inorganic phosphates, nitrophenylphosphate, pyrophosphate, tripolyphosphate, organophosphate esters. / Chemistry / D. Phil (Chemistry)

Dephosphorylation

Phosphorylation

Ion selective electrodes

Phosphate ion selective electrode

Decontamination

Electromotive force

Potential difference

Selectivity coefficient

Calibration

Ionic strength

Hydrolysis

Inorganic phosphates

Nitrophenylphosphate

Pyrophosphate

Tripolyphosphate

Organophosphate esters

541.39

Phosphate esters

Electrodes, Ion selective

Calibration

Phosphates

Solid state chemistry

Elucidation of Inositol Polyphosphate Dephosphorylation Pathways using Stable-Isotope Labelling and NMR spectroscopy

Nguyen Trung, Minh

29 September 2023

Inositolpolyphosphate (InsPs) bilden eine ubiquitäre Gruppe an hochphosphorylierten, intrazellulären Signalmolekülen in eukaryotischen Zellen. Trotz deren Beteiligung an unzähligen biologischen Prozessen bleibt die Detektion von InsPs (insb. einzelner Enantiomere) eine Herausforderung, da die momentan verfügbaren Analysemethoden immer noch limitiert sind. In der vorliegenden Arbeit wird die stabile Isotopenmarkierung von myo-Inositol (Ins) und InsPs in Kombination mit Kernspinresonanzspektroskopie (engl. Nuclear Magnetic Resonance spectroscopy, NMR) erkundet, um diese Lücke zu schließen. Die Abhängigkeit von NMR-Daten und chemischer Struktur erlaubte die Analyse komplexer Mixturen aus InsPs aus in vitro-Experimenten und biologischen Proben. Durch stereospezifische 13C-Markierung konnten sogar Enantiomere voneinander unterschieden werden. Mit Hilfe dieser Methode wurden mehrere InsP-Stoffwechselwege untersucht. Als Erstes wurde das menschliche, Phytase-artige Enzym MINPP1 (engl. Multiple Inositol Polyphosphate Phosphatase 1) detailliert in vitro und in lebenden Zellen charakterisiert. Dabei wurde ein bisher unbeschriebener InsP-Stoffwechselweg in menschlichen Zellen erstmals beschrieben. Als Zweites wurden InsP verdauende Bakterien aus der menschlichen Darmflora untersucht, sodass der Abbauweg von Inositolhexakisphosphat beleuchtet werden konnte. Als Drittes wurden DUSP-Enzyme (engl. Dual-Specificity Phosphatases) identifiziert und in vitro charakterisiert, die in der Lage sind, die Phosphoanhydrid-Bindung von Inositolpyrophosphaten (PP-InsPs) zu spalten. Die vorliegende Arbeit demonstriert, dass 13C-Markierung in Verbindung mit NMR ein mächtiges Werkzeug darstellt, um InsP-Stoffwechselvorgänge zu untersuchen. / Inositol polyphosphates (InsPs) comprise a ubiquitous group of densely phosphorylated intracellular messengers in eukaryotic cells. Despite their contributions to a myriad of biological processes the detection of InsPs remains challenging to this day, especially with regards to differentiating enantiomers, as the available analytical toolset is still limited. In this thesis the use of stable isotope labelling of myo-inositol (Ins) and InsPs is explored to address this shortcoming. Combining 13C-labelling and nuclear magnetic resonance spectroscopy (NMR) provides both enhanced sensitivity and makes use of NMR’s strong structure-data dependency. This enabled the deconvolution of complex mixtures of InsPs from in vitro experiments or biological samples. With stereo-specific 13C-labels InsP mixtures could be resolved to individual enantiomers. Using this technique several InsP metabolic pathways were examined. Firstly, the human phytase-like enzyme Multiple Inositol Polyphosphate Phosphatase (MINPP1) was characterized in depth in vitro and in living cells, establishing a hitherto undescribed inositol polyphosphate metabolic path in humans. Secondly, inositol phosphate digesting bacteria isolated from the human gut microbiome were investigated, shedding light on the metabolic fate of inositol hexakisphosphate in the digestive track. Thirdly, a set of Dual-Specificity Phosphatases (DUSPs) were identified to be able to hydrolyze the phosphoanhydride bond of inositol pyrophosphates (PP-InsPs) and characterized in vitro. The 13C-labelling approach of InsPs in junction with NMR represents a powerful tool for the study of inositol polyphosphate metabolism. In the thesis at hand, this method has facilitated our understanding of inositol polyphosphate pathways and it will be continuing doing so in the future in several biological contexts.

myo-Inositolpolyphosphate

Inositolpyrophosphate

MINPP1

Phytase

Dephosphorylierung

NMR-Spektroskopie

Isotopen-Markierung

13C-Markierung

DUSP

intestinales Mikrobiom

kurzkettige Fettsäuren

Stoffwechselfluss-Analyse

Metabolitmarkierung

myo inositol polyphosphate

inositol pyrophosphate

MINPP1

phytase

dephosphorylation

NMR spectroscopy

isotope-label

13C-label

DUSP

dual-specificity phosphatase

gut microbiome

short-chain fatty acids

metabolic flux analysis

metabolic labelling

572 Biochemie

ddc:572