Synthesis of a suite of bioorthogonal glutathione S-transferase substrates and their enzymatic incorporation for protein immobilization.

Label-free protein immobilization allows precise detection of biomolecular events. Preserving enzyme function is intrinsically challenging for these strategies. Considering that glutathione S-transferase (GST) is a broadly employed enzymatic fusion tag, we reported a label-free self-catalyzed immobilization for Schistosoma japonicum GST. We now report the synthesis, structure, and enzymology of a set of 20 smSNAREs (small molecule SNAr-electrophiles). These smSNAREs mimic (electronically) the canonical GST substrate 1-chloro-2,4-dinitrobenzene (CDNB), and bear a wide variety of bioorthogonal functionalities such as alkynes, aldehydes, acetals, and azides. Sixteen analogues including the chloro- and nitro-substituted 1, 3, 5, 6, 7, 11, 12, and 13 participated in the GST-catalyzed conjugation, indicating the substrate tolerance of the enzymatic H-site of SjGST. Using UV-vis spectroscopy, we estimate the efficiency of conjugation as a function of substrate diversity. Using LC-MS, we characterized the conjugates formed under each enzymatic transformation. Significant deviations from the canonical CDNB architecture are tolerated. Relative rates between nitro and chloro substituents indicate the nucleophilic addition step is rate determining. Enzyme immobilization on glass slides is affected by additional surface interactions and therefore does not reflect kinetic profiles observed in solution. This new class of heterobifunctional linkers enables a single-step and uniform protein capture on designer surfaces.

Human glutathione S-transferase A (GSTA) family genes are regulated by steroidogenic factor 1 (SF-1) and are involved in steroidogenesis.

Steroidogenic factor 1 (SF-1) is a master regulator for steroidogenesis. In this study, we identified novel SF-1 target genes using a genome-wide promoter tiling array and a DNA microarray. SF-1 was found to regulate human glutathione S-transferase A (GSTA) family genes (hGSTA1-hGSTA4), a superfamily of detoxification enzymes clustered on chromosome 6p12. All hGSTA genes were up-regulated by transduction of SF-1 into human mesenchymal stem cells, while knockdown of endogenous SF-1 in H295R cells down-regulated all hGSTA genes. Chromatin immunoprecipitation assays, however, revealed that SF-1 bound directly to the promoters of hGSTA3 and weakly of hGSTA4. Chromosome conformation capture assays revealed that the coordinated expression of the genes was based on changes in higher-order chromatin structure triggered by SF-1, which enables the formation of long-range interactions, at least between hGSTA1 and hGSTA3 gene promoters. In steroidogenesis, dehydrogenation of the 3-hydroxy group and subsequent Δ(5)-Δ(4) isomerization are thought to be enzymatic properties of 3ß-hydroxysteroid dehydrogenase (3ß-HSD). Here, we demonstrated that, in steroidogenic cells, the hGSTA1 and hGSTA3 gene products catalyze Δ(5)-Δ(4) isomerization in a coordinated fashion with 3ß-HSD II to produce progesterone or Δ(4)-androstenedione from their Δ(5)-precursors. Thus, hGSTA1 and hGSTA3 gene products are new members of steroidogenesis working as Δ(5)-Δ(4) isomerases.

Produccion de beta-glucosidasas por cultivos de bacterias termofilas indigenas del altiplano boliviano / beta-Glucoside production by thermophilic bacteria indigenous the bolivian altiplano culture

Las beta-glucosidasas son enzimas que poseen actividad hidrolitica y transferasa o transglucosidasa. Tienen diversas aplicaciones; en la biosintesis de oligosacaridos, produccion de etanol utilizando residuos agricolas y en la industria de vinos. La aplicacion industrial, sin embargo, requiere estabilidad a temperaturas elevadas, por lo que los microorganismos termofilos tienen gran interes. El proposito de esta investigacion es el de optimizar el medio de cultivo anaerobio de bacterias termofilas, para aumentar la produccion de beta-glucosidasas. Esta enzima es producida por tres aislados bacterianos: FT3, 2B y P5 los cuales fueron aislados de la region andina de Bolivia. El aislado bacteriano FT3 mostro una actividad beta-glucosidasa de 0,35 [UI/mL]. Se tomaron como variables dentro de la optimizacion del medio de cultivo las fuentes de nitrogeno y de carbono, y el pH. Asi tambien se probaron dos sistemas de cultivo: celulas libres y encapsuladas. Empleando extracto de levadura como fuente de nitrogeno se obtuvo una actividad de 0,52 [UI/mL]. En la optimizacion del pH del medio de cultivo se obtuvo una actividad de 0,81 [UI/mL] a pH 5. Como fuente de carbono se eligieron los hidrolizados de paja de trigo y paja de quinoa lleg¨¢ndose a obtener actividades de 1,27 y 1,34 [UI/mL] respectivamente. Se establecio que la localizacion celular de la enzima beta-glucosidasa es extracelular y presenta estabilidad hasta una temperatura de 80 ºC y un pH de 7.

The beta-glucosidases possess hydrolytic and transferase activity or transglucosidase. They have various applications; such as biosynthesis of oligosaccharides, production of ethanol using agricultural residues and wine industry. However for industrial application, stability to high temperatures is needed. Therefore a great interesting in the thermophile microorganism study exist. The purpose of this research is to optimize the culture medium of thermophilic anaerobic bacteria to increase the production of beta-glucosidase. This enzyme is produced by three isolate bacterial FT3, 2B and P5 which were isolated from the Andean region of Bolivia. FT3 isolate showed beta-glucosidase activity of 0.35 [IU/mL]. In regards to the optimization of culture medium variables such as nitrogen source, carbon source and pH were taken into account and also the combination with free and encapsulated bacterial cells. Yeast extract was the selected source of nitrogen obtaining an activity of 0.52 [IU/ mL]. The optimal pH was 5 obtaining an activity of 0.81 [IU/mL]. The selected carbon source was the hydrolyzed wheat straw and quinoa straw obtaining activities of 1.27 and 1.34 [IU/mL], respectively. The cellular localization of beta-glucosidase enzyme is extracellular and provides stability to temperature of 80 ºC and stability at pH 7.

Guinea pig liver Mu-class glutathione S-transferase M1-2 cross-reacts with antibodies to both rat Mu- and theta-class glutathione S-transferases.

Two novel major heterodimeric Mu-class glutathione (GSH) S-transferases (GSTs), designated M1-2 and M1-3*, were isolated from guinea pig (gp) liver cytosol and purified to homogeneity together with a known major homodimeric Mu-class gpGSTM1-1 (reported as GST b by R. Oshino, K. Kamei, M. Nishioka, and M. Shin, 1990, J. Biochem. 107, 105-110). These three gpGSTs were quantitatively retained on an S-hexyl-GSH affinity column and separated as homogeneous proteins by chromatofocusing. Subunits of the heterodimers were inseparable on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but could be completely separated by reverse-phase partition high-performance liquid chromatography. A molecular cloning study demonstrated that the gpGST subunit M2 consisted of 217 amino acid residues with a calculated molecular mass of 25,562 and shared 84% identity in overall amino acid sequence with gpGSTM1-1. N-terminal amino acid sequences of peptides from the gpGST subunit M3* with a blocked N-terminus strongly suggested that it should belong to the Mu class. Western blot analysis using antisera raised against purified rat (r) GSTsA1-2 (Alpha), M1-1, P1-1 (Pi), and T2-2 (Theta) indicated that gpGSTsM1-1 and M1-3* cross-reacted only with anti-rGSTM1 antibody. However, gpGSTM1-2 cross-reacted intensely to almost the same extent with antibodies to both rGSTsM1-1 and T2-2. A homodimeric gpGSTM2-2, artificially constructed from native gpGSTM1-2 by treatment with guanidine hydrochloride followed by dialysis, intensely cross-reacted with antibodies to both the rat Mu- and Theta-class GSTs. Thus, the gpGST subunit M2 provided the first evidence for the double immuno-cross-reaction of a GST with polyclonal antibodies to two different classes of GSTs.