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Advanced glycation of proteins : molecular characteristics and cellular responsesArbordo-Adesida, Evelyn Adjeley January 1998 (has links)
No description available.
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Alpha-Dicarbonyle in Lebensmitteln und glucosehaltigen Lösungen der PeritonealdialyseWeigel, Kai U., January 2004 (has links)
Dresden, Techn. Univ., Diss., 2004.
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Glutathione-dependent metabolism of electrophilic compounds by bacteriaEvans, Gareth J. January 2000 (has links)
The work presented investigates various aspects of glutathione-dependent electrophile metabolism in bacteria. First, we studied the response of <I>Staphyloccocus aureus</I> to the electrophile methylglyoxal. We found that under our experimental conditions, this organism is incapable of methylglyoxal metabolism by either glutatione-dependent or independent mechanisms. Glutatione was found to sensitise <I>S. aureus</I> to methylglyoxal. Furthermore, the sulphydryl group of glutathione is essential in this process. This implies that a glutathione conjugate may be involved in the increased sensitivity. Methylglyoxal does not activate K<sup>+</sup> efflux from <I>S. aureus</I> cells, suggesting that the KefB K<sup>+</sup> efflux system is absent from this organism. NEM activates a slow release of K<sup>+</sup> indicating that the KefC system may be present. We investigated the response of <I>E. coli</I> and <I>Pseudomonas</I> sp. to the electrophilic herbicide alachlor. This compound activates a release of K<sup>+</sup> from <I>E.coli</I> but not from any Pseudomona tested. K<sup>+</sup> efflux is not mediated by KefB, KefC or the major mechanosensitive channels. In addition to the K<sup>+</sup> efflux, alachlor stimulated an increase in the absorbance at 265 nm of media containing <I>E. coli</I>. It is not fully understood what this absorbance increase represents but it may reflect an increase in the solubility of alachlor over time. Despite its potential toxicity, alachlor did not affect the growth of either <I>E. coli</I> or <I>P. fragi</I>. However, when <I>E. coli</I> were treated with EDTA they became sensitive to alachlor. This result and data obtained using <sup>14</sup>C-labelled alachlor indicated that alachlor does not normally enter <I>E. coli</I> cells. Finally, we investigated the response of <I>E. coli</I> expressing <I>dcm</I>A from <I>Methylophilus</I> sp. DM11 to DCM. Addition of DCM resulted in immediate cessation of growth, which was not due to formaldehyde accumulation. Cells washed free of DCM after a short incubation resume growth at the pre-addition rate, indicating DCM dehalogenation causes no permanent damage to the cell.
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Metabolism of Methylglyoxal by Scenedesmus QuadricaudaRounsavall, Terry Yale 12 1900 (has links)
This report describes the effects of methylglyoxal on several green and blue-green algae, its correlation with photosynthesis, and a possible explanation of its metabolic role in the algae.
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alpha- Dicarbonyle in Lebensmitteln und glucosehaltigen Lösungen der PeritonealdialyseWeigel, Kai 11 October 2004 (has links) (PDF)
Das Vorkommen von alpha-Dicarbonylverbindungen werden in 2 Schwerpunkten dokumentiert. Zum einen werden mehrere Honige auf Ihren Gehalt an 3-DG, GO und MGO neben HMF analysiert und die Bildung wärend einer Lagerung beobachtet. Zum anderen wird die Entstehung von alpha-Dicarbonylen und anderen cytotoxischen Glucoseabbauprodukten bei der Behandlung von Lösungen der Peritonealdialyse mit hohen Druck beobachtet.
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Role of methylglyoxal in the pathogenesis of hypertensionWang, Xiaoxia 14 December 2007
Methylglyoxal (MG), a metabolite of glucose, causes non-enzymatic glycation of proteins to form irreversible advanced glycation end products (AGEs). Increased MG production, which in turn gives rise to AGEs, has been linked to the development of complications in diabetes. However, the role of MG and AGEs in hypertension has not been investigated widely. The previous study from our laboratory showed that the cellular levels of MG and MG-induced AGE formation are significantly higher in cultured aortic smooth muscle cells from spontaneously hypertensive rats (SHR) than those from normotensive Wistar-Kyoto rats (WKY). Using immunofluorescence staining with specific monoclonal antibodies against MG-induced AGEs, the present studies show a strong association of MG and its AGE products (Nå-carboxyethyl-lysine and Nå-carboxymethyl-lysine) with hypertension in SHR. The blood pressure of SHR was not different from that of WKY rats at 5 wks of age. From 8 wks onwards, blood pressure was significantly elevated compared to age-matched WKY rats. Importantly, this increase in blood pressure coincided with an elevated MG level in plasma and aorta of SHR in an age-dependent fashion compared to age-matched WKY rats, although no difference was observed in blood glucose levels between these two strains. Our data showed an increased MG level in plasma and aorta, but not in kidney or heart, in SHR at an early age of 8 wks, suggesting, in addition to diabetes/hyperglycemic or hyperlipidemic conditions, the accumulation of MG in blood vessel walls plays an important role in the development of hypertension or its complications even in the absence of diabetes. Moreover, we observed increased blood pressure and vascular remodeling in Sprague Dawley rats which had been treated to increase endogenous MG and related AGEs. After inhibiting MG and MG-induced AGE generation in SHR, hypertension development in this genetic hypertension model was delayed and vascular remodeling was reversed. Our data indicate that increased MG and AGE formation may play an important role in the development of hypertension.
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Biochemical and Biophysical Investigations of Non-Zinc Dependent Glyoxalase I EnzymesSukdeo, Nicole January 2008 (has links)
The principal methylglyoxal (MG)-detoxifying system in most living organisms is the two metalloenzyme Glyoxalase system. Glyoxalase I (GlxI) initially converts the non-enzymatically formed MG-GSH hemithioacetal to the thioester S,D-lactoylglutathione. The hydrolase, Glyoxalase II(GlxII) regenerates GSH and liberates the product D-lactate. Ni2+/Co2+- and Zn2+-activated GlxI enzymes exist in nature. The Ni2+/Co2+-activated GlxI are not active as Zn2+-holoenzymes in spite of the structural similarities to the Zn2+-dependent enzymes. The Zn2+-GlxI enzymes have been investigated heavily relative to the Ni2+/Co2+-activated enzymes, which have been isolated more recently. As part of this study the three GlxI homologs isolated from Pseudomonas aeruginosa were
characterized. The homologous genes encode GlxI enzymes of both metal activation type. The Zn2+-activated P. aeruginosa GlxI is difficult to de-metallate compared to the Ni2+/Co2+-activated enzymesreflecting a difference in metal-binding/insertion between the two types of GlxI. The E. coli GlxII was isolated and characterized to determine whether Ni2+/Co2+-activation is a characteristic of the Glx system as a whole in this organism. Inductively coupled plasma mass spectrometry on purified E. coli GlxII confirms that the active protein is a binuclear Zn2+-metalloenzyme. The results to date indicate a detectable isotope effect for the Cd2+-holoenzyme but not the Ni2+-reconstituted enzyme. Chemical
crosslinking experiments indicate that the SlyD Ni2+ metallochaperone does not form a complex with E.coli GlxI. This indicates that the E. coli active site is not metallated in vivo by this accessory
protein. The principal biophysical experiment in this project was determining of Ni2+-binding stoichiometry for E. coli GlxI by 1H-15N heteronuclear single quantum coherence (HSQC) NMR. The GlxI dimer reorganization ceases when the metal:dimer stoichiometry reaches 0.5 during apoenzyme
titration. This finding supports previous studies that indicate half-of-the-sites metal binding in this enzyme.
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Biochemical and Biophysical Investigations of Non-Zinc Dependent Glyoxalase I EnzymesSukdeo, Nicole January 2008 (has links)
The principal methylglyoxal (MG)-detoxifying system in most living organisms is the two metalloenzyme Glyoxalase system. Glyoxalase I (GlxI) initially converts the non-enzymatically formed MG-GSH hemithioacetal to the thioester S,D-lactoylglutathione. The hydrolase, Glyoxalase II(GlxII) regenerates GSH and liberates the product D-lactate. Ni2+/Co2+- and Zn2+-activated GlxI enzymes exist in nature. The Ni2+/Co2+-activated GlxI are not active as Zn2+-holoenzymes in spite of the structural similarities to the Zn2+-dependent enzymes. The Zn2+-GlxI enzymes have been investigated heavily relative to the Ni2+/Co2+-activated enzymes, which have been isolated more recently. As part of this study the three GlxI homologs isolated from Pseudomonas aeruginosa were
characterized. The homologous genes encode GlxI enzymes of both metal activation type. The Zn2+-activated P. aeruginosa GlxI is difficult to de-metallate compared to the Ni2+/Co2+-activated enzymesreflecting a difference in metal-binding/insertion between the two types of GlxI. The E. coli GlxII was isolated and characterized to determine whether Ni2+/Co2+-activation is a characteristic of the Glx system as a whole in this organism. Inductively coupled plasma mass spectrometry on purified E. coli GlxII confirms that the active protein is a binuclear Zn2+-metalloenzyme. The results to date indicate a detectable isotope effect for the Cd2+-holoenzyme but not the Ni2+-reconstituted enzyme. Chemical
crosslinking experiments indicate that the SlyD Ni2+ metallochaperone does not form a complex with E.coli GlxI. This indicates that the E. coli active site is not metallated in vivo by this accessory
protein. The principal biophysical experiment in this project was determining of Ni2+-binding stoichiometry for E. coli GlxI by 1H-15N heteronuclear single quantum coherence (HSQC) NMR. The GlxI dimer reorganization ceases when the metal:dimer stoichiometry reaches 0.5 during apoenzyme
titration. This finding supports previous studies that indicate half-of-the-sites metal binding in this enzyme.
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Role of methylglyoxal in the pathogenesis of hypertensionWang, Xiaoxia 14 December 2007 (has links)
Methylglyoxal (MG), a metabolite of glucose, causes non-enzymatic glycation of proteins to form irreversible advanced glycation end products (AGEs). Increased MG production, which in turn gives rise to AGEs, has been linked to the development of complications in diabetes. However, the role of MG and AGEs in hypertension has not been investigated widely. The previous study from our laboratory showed that the cellular levels of MG and MG-induced AGE formation are significantly higher in cultured aortic smooth muscle cells from spontaneously hypertensive rats (SHR) than those from normotensive Wistar-Kyoto rats (WKY). Using immunofluorescence staining with specific monoclonal antibodies against MG-induced AGEs, the present studies show a strong association of MG and its AGE products (Nå-carboxyethyl-lysine and Nå-carboxymethyl-lysine) with hypertension in SHR. The blood pressure of SHR was not different from that of WKY rats at 5 wks of age. From 8 wks onwards, blood pressure was significantly elevated compared to age-matched WKY rats. Importantly, this increase in blood pressure coincided with an elevated MG level in plasma and aorta of SHR in an age-dependent fashion compared to age-matched WKY rats, although no difference was observed in blood glucose levels between these two strains. Our data showed an increased MG level in plasma and aorta, but not in kidney or heart, in SHR at an early age of 8 wks, suggesting, in addition to diabetes/hyperglycemic or hyperlipidemic conditions, the accumulation of MG in blood vessel walls plays an important role in the development of hypertension or its complications even in the absence of diabetes. Moreover, we observed increased blood pressure and vascular remodeling in Sprague Dawley rats which had been treated to increase endogenous MG and related AGEs. After inhibiting MG and MG-induced AGE generation in SHR, hypertension development in this genetic hypertension model was delayed and vascular remodeling was reversed. Our data indicate that increased MG and AGE formation may play an important role in the development of hypertension.
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Studies of methylglyoxal synthase: the distribution of enzyme and chemical mechanism of catalysisYuan, Pau-Miau 05 1900 (has links)
Methylgloxal synthase, which catalyzes the conversion of dihydroxyacetone phosphate to methylglyoxal and inorganic phosphate, has been found in several Enterobacteriaceae. The enzyme along with glyoxalase I and II and D-lactate oxidase, therefore, constitute a nonphosphorylated shunt of the normal glycolytic pathway
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