A Characterization of Liver Glyoxalase I From Normal Mice and Mice Bearing Lymphosarcoma

Strzinek, Robert Alfred

08 1900

The purpose of this investigation was (1) to isolate and purify glyoxalase I from the livers of normal DBA/lJ mice and the livers from mice bearing a lymphosarcoma tumor; and (2) to determine, at least with respect to glyoxalase I, if the tumor has an effect on the chemical properties or structure of macromolecules in an organ removed from tumor locale and not histologically affected by its presence.

liver glyoxalase I

mice

lymphosarcoma

Hodgkin's disease.

Glyoxalase.

Synthesis and Study of Glutaryl-S-(ω-aminoalkyl)-L-cysteinylglycines as Inhibitors of Glyoxalase I

Phillips, Gerald Wayne

05 1900

This thesis describes the synthesis and preliminary enzymatic study of glutaryl-S-(8-aminooctyl)-L-cysteinylglycine and glutaryl-S-(10-aminodecyl)-L-cysteinylglycine as inhibitors of glyoxalase I. These analogs of glutathione were prepared as potential ligands for affinity chromatography purification of glyoxalase I. The compounds were synthesized by a seven-step procedure in overall yields of 24% for the octyl analog and 33% for the decyl analog. Both compounds exhibited mixed type inhibition of the enzyme, with the decyl derivative being more inhibitory than the octyl derivative. The inhibition was nonlinear (parabolic) for both compounds. Although less inhibitory than the corresponding S-substituted glutathione derivatives, these analogs are promising candidates for affinity chromatography ligands. Such compounds may also be useful in studying the mechanism of glyoxalase I.

glyoxalase I

analogs of glutathione

Enzyme inhibitors.

Glyoxalase.

Glutathione.

Methylglyoxal, glyoxalases and cell proliferation

Hooper, Nigel I.

January 1987

The metabolic function of the glyoxalase system was investigated in (a) the differentiation and proliferation of human tumour cells in vitro, (b) the cell-free assembly of microtubules and (c) in the red blood cells during hyperglycaemia associated with Diabetes Mellitus. Chemically-induced differentiation of human promyelocytic HL60 leukaemia cells to neutrophils, and K562 erythroleukaemia cells, was accompanied by a decrease and an increase in the activity of glyoxalase I, respectively. Growth-arrest of Burkitt's lymphoma Raji cells and GM892 lymphoblastoid cells was accompanied by an increase and a decrease in the activity of glyoxalase I respectively. However, differentiation and growth arrest generally proceeded with an increase in the activity of glyoxalase II. Glyoxalase I activity did not consistently correlate with cell differentiation or proliferation status; hence, it is unlikely that glyoxalase I activity is either an indicator or a regulator of cell differentiation or proliferation. Conversely, glyoxalase II activity consistently increased during cell differentiation and growth-arrest and may be both an indicator and regulator of cell differentiation or proliferation. This may be related to the control of cellular microtubule assembly. S-D-Lactoylglutathione potentiated the cell-free, GTP-promoted assembly of microtubules. The effect was dose-related and was inhibited by glyoxalase II. During assembly, S-D-lactoylglutathione was consumed. This suggests that the glyoxalase system, through the influence of S-D-lactoylglutathione, may regulate the assembly of microtubules in cellular systems The whole blood concentrations of methylglyoxal and S-D-lactoylglutathione were increased in Diabetes Mellitus. There was no significant difference between red blood cell glyoxalase activities in diabetics, compared to healthy controls. However, insulin-dependent diabetic patients with retinopathy had a significantly higher glyoxalase I activity and a lower glyoxalase II activity, than patients without retinopathy. Diabetic retinopathy correlated with high glyoxalase I activity and low glyoxalase II activity and suggests the glyoxalase system may be involved in the development of diabetic complications.

572

Pharmacy ; Glyoxalase metabolic function

Over-Expression and Characterization of a Glyoxalase 2 Like Enzyme

Limphong, Pattraranee

14 August 2009

No description available.

Biochemistry

Biophysics

Chemistry

Glyoxalase 2

FUNCTIONAL CHARACTERIZATION OF Arabidopsis thaliana GLYOXALASE 2-LIKE ENZYMES

Devanathan, Sriram

22 November 2011

No description available.

Biochemistry

Glyoxalase 2

Arabidopsis thaliana Glyoxalase

metabolomics

abiotic stress in arabidopsis

glyoxalase

ETHE1

GLX2-1

sriram devanathan

Biochemical and Biophysical Investigations of Non-Zinc Dependent Glyoxalase I Enzymes

Sukdeo, Nicole

January 2008

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.

Glyoxalase

methylglyoxal

metalloenzyme

enzymology

nickel

zinc

Chemistry

Biochemical and Biophysical Investigations of Non-Zinc Dependent Glyoxalase I Enzymes

Sukdeo, Nicole

January 2008

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.

Glyoxalase

methylglyoxal

metalloenzyme

enzymology

nickel

zinc

Chemistry

Investigation of the Microbial Glyoxalase System

Suttisansanee, Uthaiwan

January 2011

The Glyoxalase system is composed of two metalloenzymes, Glyoxalase I and Glyoxalase II, that catalyze the conversion of toxic, metabolically produced alpha-ketoaldehydes, such as methyglyoxal, in the presence of a thiol cofactor, such as glutathione, into their corresponding nontoxic 2-hydroxycarboxylic acids, leading to detoxification of these cellular metabolites. Previous studies on the first enzyme in the Glyoxalase system, Glyoxalase I (GlxI), in yeast, protozoa, animals, human, plants and Gram-negative bacteria suggest two metal activation classes, zinc-activation or non-zinc-activation (but exhibiting selective nickel/cobalt-activation). This thesis provides the key discoveries of the Glyoxalase system from Gram-positive microorganisms using the major thiol cofactor/cosubstrate that produced within that particular organisms as well as the relatedness of the proteins in the same beta-alpha-beta-beta-beta protein superfamily.

Glyoxalase

Metalloenzyme

Bacterial enzyme

Superfamily

Chemistry

Investigation of the Microbial Glyoxalase System

Suttisansanee, Uthaiwan

January 2011

The Glyoxalase system is composed of two metalloenzymes, Glyoxalase I and Glyoxalase II, that catalyze the conversion of toxic, metabolically produced alpha-ketoaldehydes, such as methyglyoxal, in the presence of a thiol cofactor, such as glutathione, into their corresponding nontoxic 2-hydroxycarboxylic acids, leading to detoxification of these cellular metabolites. Previous studies on the first enzyme in the Glyoxalase system, Glyoxalase I (GlxI), in yeast, protozoa, animals, human, plants and Gram-negative bacteria suggest two metal activation classes, zinc-activation or non-zinc-activation (but exhibiting selective nickel/cobalt-activation). This thesis provides the key discoveries of the Glyoxalase system from Gram-positive microorganisms using the major thiol cofactor/cosubstrate that produced within that particular organisms as well as the relatedness of the proteins in the same beta-alpha-beta-beta-beta protein superfamily.

Glyoxalase

Metalloenzyme

Bacterial enzyme

Superfamily

Chemistry

Metabolism of Methylglyoxal by Scenedesmus Quadricauda

Rounsavall, Terry Yale

06 1900

The purpose of this study was to investigate the metabolic pathways of methylglyoxal in S. quadricauda.

glyoxalase

methylglyoxal

Scenedesmus quadricauda

biology

metabolism