Activation of oligopeptidase B from Streptomyces griseus by thiol-reacting reagents is independent of the single reactive cysteine residue.

Oligopeptidase B from Streptomyces griseus was cloned and characterized to clarify the substrate recognition mechanism and the role of a reactive cysteine residue in family S9 prolyl oligopeptidases (POPs). The cloned enzyme, SGR-OpdB, was annotated as a putative family S9 prolyl oligopeptidase based on its deduced amino acid sequence, in which a sole cysteine residue Cys(544) is present close to the catalytic Asp residue in the C-terminal region. The protein was identified as oligopeptidase B, a member of the subfamily S9a of the family S9 POPs, as judged by its substrate specificity and enzymatic characteristics. Its enzymatic activity was markedly enhanced by high NaCl concentration and the reducing reagents dithiothreitol (DTT) and reduced glutathione (GSH). It is particularly interesting that oxidized glutathione (GSSG) also enhanced SGR-OpdB activity. The SGR-OpdB C544A mutant was constructed and characterized to clarify the role of the putative reactive Cys residue, Cys(544). Surprisingly, the enzymatic activity of the Cys-free mutant was also markedly activated by the general thiol-reacting reagent DTT, GSH, and GSSG. To our knowledge, this is the first report of activity-enhancing effects of thiol-reacting reagents toward Cys-free enzymes. Results clarified the role of additives in inducing conformational change of SGR-OpdB into active peptidase.

Change in substrate preference of Streptomyces aminopeptidase through modification of the environment around the substrate binding site.

We attempted to alter the substrate preference of aminopeptidase from Streptomyces septatus TH-2 (SSAP). Because Asp198 and Phe221 of SSAP are located in the substrate binding site, we screened 2,000 mutant enzymes with D198X/F221X mutations. By carrying out this examination, we obtained two enzymes; one specifically hydrolyzed an arginyl derivative, and the other specifically hydrolyzed a cystinyl derivative (65- and 12.5-fold higher k(cat) values for hydrolysis of p-nitroanilide derivatives than those of the wild type, respectively).

Study on peptide hydrolysis by aminopeptidases from Streptomyces griseus, Streptomyces septatus and Aeromonas proteolytica.

We developed a spectrophotometric assay for peptide hydrolysis by aminopeptidases (APs). The assay enables the measurement of free amino acids liberated by AP-catalyzed peptide hydrolysis using 4-aminoantipyrine, phenol, peroxidase, and L-amino acid oxidase. We investigated the specificity of bacterial APs [enzymes from Streptomyces griseus (SGAP), Streptomyces septatus (SSAP), and Aeromonas proteolytica (AAP)] toward peptide substrates using this assay method. Although these enzymes most efficiently cleave leucyl derivatives among 20 aminoacyl derivatives, in peptide hydrolysis, the catalytic efficiencies of Phe-Phe hydrolysis by SGAP and SSAP exceed that of Leu-Phe hydrolysis. Furthermore, all enzymes showed the maximum catalytic efficiencies for Phe-Phe-Phe hydrolysis. These results indicate that the hydrolytic activities of bacterial APs are affected by the nature of the penultimate residue or flanking moiety and the length of the peptide substrate.

Change in the redox state of glutathione regulates differentiation of tracheary elements in Zinnia cells and Arabidopsis roots.

Exogenously applied GSH and GSSG can control the in vitro differentiation of mesophyll cells to tracheary elements (TEs) in Zinnia elegans, and de novo GSH synthesis is essential for the early differentiation. The purpose of the present study is to address how GSH and GSSG control TE differentiation. GSSG transiently accumulated during the in vitro TE differentiation and exogenously applied GSSG down-regulated transcript levels of GSSG reductase (GR), an enzyme maintaining glutathione in a reduced redox state, while there were no significant changes in transcript levels of enzymes involved in GSH synthesis. Transgenic Arabidopsis overexpressing the GR gene showed delayed TE formation in the root, which was attributed to the suppression of cell division. Exogenously applied GSH had an effect similar to overexpression of the GR gene. These findings suggest that reduced states of glutathione suppress TE differentiation. In wild-type Arabidopsis, TE formation was promoted by application of GSSG at an appropriate concentration, but was suppressed at higher concentrations. A T-DNA-inserted knockout mutant of cytosolic GR exhibited delayed TE formation; this phenotype was little affected by GSSG application. Taken together, the process of the redox changes in glutathione is considered to be controlled via GR activity for TE differentiation.

Genetic screening of Hrp type III-related pathogenicity genes controlled by the HrpB transcriptional activator in Ralstonia solanacearum.

As in many other Gram-negative phytopathogenic bacteria, the Hrp type III secretion system is essential for the pathogenicity of Ralstonia solanacearum on host plants. The expression of most of the type III effector genes previously isolated from R. solanacearum is co-regulated with those of hrp genes by an AraC-type transcriptional activator, HrpB. In order to isolate type III-related pathogenicity genes, we screened hrpB-regulated genes in R. solanacearum. Using a transposon-based system, we isolated 30 novel hpx (hrpB-dependent expression) genes outside the hrp gene cluster. Most of the hpx genes contain a PIP (plant-inducible promoter) box-like motif in their putative promoter regions. Seven hpx genes encoded homologues of known type III effectors and type III-related proteins found in other animal and plant pathogens. Four encoded known enzymes, namely, glyoxalase I, Nudix hydrolase, spermidine synthase and transposase. Interestingly, six hpx genes encoded two types of leucine-rich repeat (LRR) protein. Products of the remaining genes did not show any significant homology to known proteins. We also identified two novel hrpB-regulated genes, hpaZ and hpaB, downstream of hrpY in the hrp cluster. The hpaB gene of R. solanacearum, but not hpaZ, was required for both the pathogenicity and ability to induce hypersensitive reaction on plants. We show that a hpaB null mutant still produces Hrp pili on the cell surface although it shows a typical Hrp-defective phenotype on plants.

Reduced glutathione is a novel regulator of vernalization-induced bolting in the rosette plant Eustoma grandiflorum.

The transition from the vegetative rosette stage to the reproductive growth stage (bolting) in the rosette plant Eustoma grandiflorum has a strict requirement for vernalization, a treatment that causes oxidative stress. Since we have shown that reduced glutathione (GSH) and its biosynthesis are associated with bolting in another rosette plant Arabidopsis thaliana, we here investigated whether a similar mechanism governs the vernalization-induced bolting of E. grandiflorum. Addition of GSH or its precursor cysteine, instead of vernalization, induced bolting but other thiols, dithiothreitol and 2-mercaptoethanol, did not. The inductive effect of vernalization on bolting was nullified by addition of buthionine sulfoximine (BSO), an inhibitor of GSH synthesis, without decreasing the plant growth rate. BSO-mediated inhibition of bolting was reversed by addition of GSH but not by cysteine. These indicate that vernalization-induced bolting involves GSH biosynthesis and is specifically regulated by GSH. Plant GSH increased during the early vernalization period along with the activity of gamma-glutamylcysteine synthetase that catalyzes the first step of GSH biosynthesis, although there was little change in amounts of GSH precursor thiols, cysteine and gamma-glutamylcysteine. These findings strongly suggest that vernalization stimulates GSH synthesis and synthesized GSH specifically determines the bolting time of E. grandiflorum.

Level of glutathione is regulated by ATP-dependent ligation of glutamate and cysteine through photosynthesis in Arabidopsis thaliana: mechanism of strong interaction of light intensity with flowering.

Glutathione (GSH) is associated with flowering in Arabidopsis thaliana, but how GSH biosynthesis is regulated to control the transition to flowering remains to be elucidated. Since the key reaction of GSH synthesis is catalyzed by gamma-glutamylcysteine synthetase (gamma-ECS) and all the gamma-ECS cDNAs examined contained extra sequences for plastid targeting, we investigated the relationships among GSH levels, photosynthesis and flowering. The GSH level in Arabidopsis increased with the light intensity. The ch1 mutants defective in a light-harvesting antenna in photosystem II showed reduced GSH levels with accumulation of the GSH precursor cysteine, and introduction of the gamma-ECS gene GSH1 under the control of the cauliflower mosaic virus 35S promoter (35S-GSH1) into the ch1 mutant altered the GSH level in response to the gamma-ECS mRNA level. These indicate that photosynthesis limits the gamma-ECS reaction to regulate GSH biosynthesis. Like the glutathione-biosynthesis-defective cad2-1 mutant, the ch1 mutants flowered late under weak-light conditions, and this late-flowering phenotype was rescued by supplementation of GSH. Introduction of the 35S-GSH1 construct into the ch1 mutant altered flowering in response to the gamma-ECS mRNA and GSH levels. These findings indicate that flowering in A. thaliana is regulated by the gamma-ECS reaction of GSH synthesis that is coupled with photosynthesis.

The sugar-metabolic enzymes aldolase and triose-phosphate isomerase are targets of glutathionylation in Arabidopsis thaliana: detection using biotinylated glutathione.

GSH has multiple actions in physiological responses of plants, but the molecular mechanisms are not fully understood. GSH plays an important role in functional alteration of proteins by reversible covalent incorporation (glutathionylation) in vertebrate cells. To investigate the function of glutathionylation in plant cells, we examined glutathionylated proteins in the suspension-cultured cells of Arabidopsis using biotinylated GSH. Biotinylated GSH was incorporated into about 20 proteins. Two of these proteins were identified as the key enzymes for sugar metabolism, triose-phosphate isomerase (TPI) and putative plastidic aldolase. Recombinant TPI was inactivated by GSSG, and it was reactivated by GSH. The physiological roles of glutathionylation of TPI and aldolase in sugar metabolism are discussed.