Expressão e atividade da NAD(P)H-oxidase de membrana nas células trofoblásticas de camundongos. / Expression and activity of the membrane NADP(H) - oxidase in the mouse trophoblast cells.

Gomes, Sara Maria Zago

15 August 2008

As células trofoblásticas provenientes de cones ectoplacentários na fase de pós-implantação expressam as subunidades do complexo NAD(P)H-oxidase de membrana p22-phox, gp91-phox, p47-phox, p40-phox, p67-phox e Rac1 previamente descritas em fagócitos e envolvidas com a atividade fagocitária destas células. Ocorre modulação da expressão das subunidades do complexo enzimático NAD(P)H-oxidase sob o estímulo com PMA, agente capaz de fosforilar a subunidade p47-phox e ativar esta enzima em fagócitos profissionais. Nossos ensaios experimentais indicam que as células trofoblásticas são capazes de gerar espécies reativas de oxigênio dependente da atividade do complexo NAD(P)H-oxidase de membrana de baixa intensidade quando não estimuladas e de forma muito mais intensa quando estimuladas pelo PMA. As características de expressão e atividade do complexo enzimático NAD(P)H-oxidase de membrana encontradas neste estudo sugerem que esta enzima é semelhante a encontrada em outros fagócitos e, desta forma possa talvez estar também envolvida com processos de defesa da interface materno-fetal. / In macrophages and neutrophils, the activation of the phagocytosis is defined by the acquisition of competence for microbicide, tumoricide and cytolytic functions resultant of generation and release of oxygen reactive species, besides the phagocytic process per se. Like these phagocytes, trophoblast cells in many species are also phagocytic. This cellular population involves completely the embryo and exhibits different and specific characteristics along the gestation. In rodents and primates, these cells are strategically positioned between maternal and fetal circulation and exhibit invasive and phagocytic activity, respectively responsible for anchorage of the embryo into the endometrium and uptake of an adequate nutritional supply for the embryo development. In rodents, these activities present a maximum degree during the implantation period, gradually declining, as the placenta develops. In the presence of strange particles at the maternal-placental interface, however, this process can be reactivated and, in this case, may be related to defense\'s mechanisms. Previous studies performed in our laboratory showed the potential of the trophoblast in producing and releasing reactive species of oxygen/nitrogen, in a very similar manner to that observed in macrophages and neutrophils. The production of such molecules is associated to different enzymes, but the localization of hydrogen peroxide on trophoblast cell surface has suggested a NAD(P)H-oxidase activity. NAD(P)H-oxidase is formed by the cytochrome b558 associated to the cellular membrane (subunits p22-phox + gp91-phox), the cytosolic subunits p47-phox, p67-phox and p40phox and, the GTPases Rac1 and Rac2 in an electron generator system that uses NADH or NADPH as substratum. Once activated, the enzymatic complex is responsible for the electron inflow to the molecular oxygen, yields superoxide anion. Thus, based on the literature and results previously obtained by our group, this study analyzed the protein and gene expression of the NAD(P)H-oxidase complex subunits respectively by immunolocalization and Westernblotting and rt-PCR, in the mouse trophoblast stimulated with PMA. Rt-PCR semi-quantitative analyses showed increase expression of the subunits p22-phox, gp91-phox, p47-phox, p67-phox, p40phox and Rac1 in PMA-treated in comparison with non treated ectoplacental cones. The expression of the subunits gp91-phox, p47-phox and p67-phox were confirmed by Western blotting and, like gene expression also increased in the presence of PMA. These subunits were mostly located in the trophoblast giant cell population, associated to the phagocytic process at the maternal-placental interface. Increased expression of such subunits may be related to an increase in the NAD(P)H-oxidase activity. To analyze this possibility and to determine the role played by NAD(P)H-oxidase activity in the reactive oxygen species produced by trophoblast cells, cellular assays were performed using the oxyethidium fluorescence, a product of dihydroethidium oxidation by superoxide anion. Thus, under PMA stimulus and antimycin A that blocks the mitochondrial NAD(P)H-oxidase activity and, apocynin and allopurinol, respectively blocking the membrane NAD(P)H-oxidase and xhantine oxidase and, still, using specific superoxide and hydrogen peroxide scavengers (superoxide dismutase enzyme and catalase) we showed the generation of reactive species of oxygen-NAD(P)H-oxidase dependent by trophoblast cells, mostly when stimulated. These results come to add important information about the potential of the trophoblast in producing reactive species at the maternal-fetal interface and, open a new investigation interest on the NADPH-oxidase regulatory processes and its involvement in defense functions of the embryo in both healthy and pathological processes that can determine the failure of the gestation.

Ânion - superóxido

Anion superoxide

Células trofoblásticas

Fagocitose

go 91 - phox

gp91 - phox

NADP(H) - oxidase

NADP(H) - oxidase

p67 - phox

p67 - phox

Phagocytosis

Trophoblast cell

Expressão e atividade da NAD(P)H-oxidase de membrana nas células trofoblásticas de camundongos. / Expression and activity of the membrane NADP(H) - oxidase in the mouse trophoblast cells.

Sara Maria Zago Gomes

15 August 2008

As células trofoblásticas provenientes de cones ectoplacentários na fase de pós-implantação expressam as subunidades do complexo NAD(P)H-oxidase de membrana p22-phox, gp91-phox, p47-phox, p40-phox, p67-phox e Rac1 previamente descritas em fagócitos e envolvidas com a atividade fagocitária destas células. Ocorre modulação da expressão das subunidades do complexo enzimático NAD(P)H-oxidase sob o estímulo com PMA, agente capaz de fosforilar a subunidade p47-phox e ativar esta enzima em fagócitos profissionais. Nossos ensaios experimentais indicam que as células trofoblásticas são capazes de gerar espécies reativas de oxigênio dependente da atividade do complexo NAD(P)H-oxidase de membrana de baixa intensidade quando não estimuladas e de forma muito mais intensa quando estimuladas pelo PMA. As características de expressão e atividade do complexo enzimático NAD(P)H-oxidase de membrana encontradas neste estudo sugerem que esta enzima é semelhante a encontrada em outros fagócitos e, desta forma possa talvez estar também envolvida com processos de defesa da interface materno-fetal. / In macrophages and neutrophils, the activation of the phagocytosis is defined by the acquisition of competence for microbicide, tumoricide and cytolytic functions resultant of generation and release of oxygen reactive species, besides the phagocytic process per se. Like these phagocytes, trophoblast cells in many species are also phagocytic. This cellular population involves completely the embryo and exhibits different and specific characteristics along the gestation. In rodents and primates, these cells are strategically positioned between maternal and fetal circulation and exhibit invasive and phagocytic activity, respectively responsible for anchorage of the embryo into the endometrium and uptake of an adequate nutritional supply for the embryo development. In rodents, these activities present a maximum degree during the implantation period, gradually declining, as the placenta develops. In the presence of strange particles at the maternal-placental interface, however, this process can be reactivated and, in this case, may be related to defense\'s mechanisms. Previous studies performed in our laboratory showed the potential of the trophoblast in producing and releasing reactive species of oxygen/nitrogen, in a very similar manner to that observed in macrophages and neutrophils. The production of such molecules is associated to different enzymes, but the localization of hydrogen peroxide on trophoblast cell surface has suggested a NAD(P)H-oxidase activity. NAD(P)H-oxidase is formed by the cytochrome b558 associated to the cellular membrane (subunits p22-phox + gp91-phox), the cytosolic subunits p47-phox, p67-phox and p40phox and, the GTPases Rac1 and Rac2 in an electron generator system that uses NADH or NADPH as substratum. Once activated, the enzymatic complex is responsible for the electron inflow to the molecular oxygen, yields superoxide anion. Thus, based on the literature and results previously obtained by our group, this study analyzed the protein and gene expression of the NAD(P)H-oxidase complex subunits respectively by immunolocalization and Westernblotting and rt-PCR, in the mouse trophoblast stimulated with PMA. Rt-PCR semi-quantitative analyses showed increase expression of the subunits p22-phox, gp91-phox, p47-phox, p67-phox, p40phox and Rac1 in PMA-treated in comparison with non treated ectoplacental cones. The expression of the subunits gp91-phox, p47-phox and p67-phox were confirmed by Western blotting and, like gene expression also increased in the presence of PMA. These subunits were mostly located in the trophoblast giant cell population, associated to the phagocytic process at the maternal-placental interface. Increased expression of such subunits may be related to an increase in the NAD(P)H-oxidase activity. To analyze this possibility and to determine the role played by NAD(P)H-oxidase activity in the reactive oxygen species produced by trophoblast cells, cellular assays were performed using the oxyethidium fluorescence, a product of dihydroethidium oxidation by superoxide anion. Thus, under PMA stimulus and antimycin A that blocks the mitochondrial NAD(P)H-oxidase activity and, apocynin and allopurinol, respectively blocking the membrane NAD(P)H-oxidase and xhantine oxidase and, still, using specific superoxide and hydrogen peroxide scavengers (superoxide dismutase enzyme and catalase) we showed the generation of reactive species of oxygen-NAD(P)H-oxidase dependent by trophoblast cells, mostly when stimulated. These results come to add important information about the potential of the trophoblast in producing reactive species at the maternal-fetal interface and, open a new investigation interest on the NADPH-oxidase regulatory processes and its involvement in defense functions of the embryo in both healthy and pathological processes that can determine the failure of the gestation.

Ânion - superóxido

Células trofoblásticas

Fagocitose

gp91 - phox

NADP(H) - oxidase

p67 - phox

Anion superoxide

go 91 - phox

NADP(H) - oxidase

p67 - phox

Phagocytosis

Trophoblast cell

Investigation of Escherichia coli Tat (Twin arginine translocase) transport in vitro

Yong, Shee Chien

January 2011

The Twin arginine translocase (Tat) system catalyzes movement of folded proteins across the cytoplasmic membrane of bacteria and the thylakoid membrane of plant chloroplasts. This transport process requires energy in the form of the transmembrane proton motive force (PMF). The Tat system can be studied in vitro using inner membrane vesicles (IMVs) from E. coli overproducing the Tat components, TatA, TatB and TatC. However, the transport efficiencies of current in vitro Tat transport assays are low. In this work, current in vitro Tat transport assays were compared and parameters that affect transport efficiencies were identified. Mild French press treatment of IMVs resulted in larger IMVs with higher transport efficiencies. Chloride ions were shown to inhibit Tat transport in vitro. Generation of a PMF by the activity of ATP synthase gave higher transport efficiencies than generating a PMF by NADH respiration. This understanding was applied to develop an optimized in vitro Tat transport assay that showed a higher transport efficiency than currently published methods. Fluorescently labelled Tat substrates were developed to allow quantitative analysis of Tat transport. The transport of the purified native Tat substrate, CueO into IMVs was characterized using the optimized in vitro Tat transport assay. It was shown that the proton concentration (ΔpH) component of the PMF was sufficient to support Tat transport in vitro. It was observed that transport of CueO ceased in a time-dependent manner in the in vitro Tat transport assays. This loss of transport efficiency could be due, at least in part, to the presence of a PMF since transport efficiency was reduced when IMVs were pre-energized. Substrates for future in vitro single molecule fluorescence microscopy studies of the Tat transport were developed in this work. One of the substrates is fluorescently labelled CueO. The second substrate is the native Tat substrate alkaline phosphatase PhoX from Vibrio fischeri which was able to cleave the fluorogenic compound AttoPhos® and can thus be used as an enzymatic reporter of Tat transport. The structure of a native Tat substrate from Pseudomonas fluorescens, PhoX, was solved by X-ray crystallography at a resolution of 1.4Å. PhoX is a monomeric six blade β propeller with two α-helical bundle subdomains. PhoX was shown to have optimum activity at pH8.0. PhoX has a novel catalytic site which requires two Fe³⁺ (including a Cys-coordinated Fe³⁺) and three Ca²⁺ as cofactors. Mutagenesis studies showed that all the metal ions are required for the integrity of the active site. Co-crystallization of PhoX with vanadate, an inhibitor of PhoX which mimics the transition state, showed that hydrolysis of phosphomonoesters does not involve formation of a covalent phosphoenzyme intermediate. Instead, dephosphorylation of substrates is proposed to occur via a SN2 reaction with OH- as the attacking nucleophile.

571.29

Impact of Secondary Interactions in Asymmetric Catalysis

Frölander, Anders

January 2007

This thesis deals with secondary interactions in asymmetric catalysis and their impact on the outcome of catalytic reactions. The first part revolves around the metal-catalyzed asymmetric allylic alkylation reaction and how interactions within the catalyst affect the stereochemistry. An OH–Pd hydrogen bond in Pd(0)–π-olefin complexes of hydroxy-containing oxazoline ligands was identified by density functional theory computations and helped to rationalize the contrasting results obtained employing hydroxy- and methoxy-containing ligands in the catalytic reaction. This type of hydrogen bond was further studied in phenanthroline metal complexes. As expected for a hydrogen bond, the strength of the bond was found to increase with increased electron density at the metal and with increased acidity of the hydroxy protons. The second part deals with the use of hydroxy- and methoxy-containing phosphinooxazoline ligands in the rhodium- and iridium-catalyzed asymmetric hydrosilylation reaction. The enantioselectivities obtained were profoundly enhanced upon the addition of silver salts. This phenomenon was explained by an oxygen–metal coordination in the catalytic complexes, which was confirmed by NMR studies of an iridium complex. Interestingly, the rhodium and iridium catalysts nearly serve as pseudo-enantiomers giving products with different absolute configurations. The final part deals with ditopic pyridinobisoxazoline ligands and the application of their metal complexes in asymmetric cyanation reactions. Upon complexation, these ligands provide catalysts with both Lewis acidic and Lewis basic sites, capable of activating both the substrate and the cyanation reagent. Lanthanide and aluminum complexes of these ligands were found to catalyze the addition of the fairly unreactive cyanation reagents ethyl cyanoformate and acetyl cyanide to benzaldehyde, whereas complexes of ligands lacking the Lewis basic coordination sites failed to do so. / QC 20100709

asymmetric catalysis

secondary interaction

hydrogen bond

chiral ligand

allylic alkylation

hydrosilylation

cyanation

pymox

box

PHOX

pybox

palladium

iridium

rhodium

Lewis acid

Lewis base

Organic chemistry

Organisk kemi

<i>Campylobacter jejuni</i> Survival Strategies and Counter-Attack: An investigation of <i>Campylobacter</i> phosphate mediated biofilms and the design of a high-throughput small-molecule screen for TAT inhibition

Drozd, Mary R.

29 August 2012

No description available.

Cellular Biology

Microbiology

Molecular Biology

Veterinary Services

Campylobacter

C. jejuni

small molecule

Twin Arginine Translocation

TAT

Biofilm

Phosphate Metabolim

phoX

ppk1

ppk2