Bioconversion of biologically active indole derivatives with indole-3-acetic acid-degrading enzymes from Caballeronia glathei DSM50014

A plant auxin hormone indole-3-acetic acid (IAA) can be assimilated by bacteria as an energy and carbon source, although no degradation has been reported for indole-3-propionic acid and indole-3-butyric acid. While significant efforts have been made to decipher the Iac (indole-3-acetic acid catabolism)-mediated IAA degradation pathway, a lot of questions remain regarding the mechanisms of individual reactions, involvement of specific Iac proteins, and the overall reaction scheme. This work was aimed at providing new experimental evidence regarding the biodegradation of IAA and its derivatives. Here, it was shown that Caballeronia glathei strain DSM50014 possesses a full iac gene cluster and is able to use IAA as a sole source of carbon and energy. Next, IacE was shown to be responsible for the conversion of 2-oxoindole-3-acetic acid (Ox-IAA) intermediate into the central intermediate 3-hydroxy-2-oxindole-3-acetic acid (DOAA) without the requirement for IacB. During this reaction, the oxygen atom incorporated into Ox-IAA was derived from water. Finally, IacA and IacE were shown to convert a wide range of indole derivatives, including indole-3-propionic acid and indole-3-butyric acid, into corresponding DOAA homologs. This work provides novel insights into Iac-mediated IAA degradation and demonstrates the versatility and substrate scope of IacA and IacE enzymes

Comparative Analysis of Mesophilic YqfB-Type Amidohydrolases

The widespread superfamily of the human activating signal cointegrator homology (ASCH) domain was identified almost 20 years ago; however, the amount of experimental data regarding the biological function of the domain is scarce. With this study, we aimed to determine the putative cellular functions of four hypothetical ASCH domain-containing amidohydrolase YqfB analogues by investigating their activity towards various N-acylated cytosine derivatives, including potential nucleoside-derived prodrugs, as well as their ability to bind/degrade nucleic acids in vitro. According to determined kinetic parameters, N4-acetylcytidine is assumed to be the primary substrate for amidohydrolases. Despite the similarity to the proteins containing the PUA domain, no nucleic acid binding activity was detected for YqfB-like proteins, suggesting that, in vivo, these enzymes are a part of the pyrimidine salvage pathway. We also demonstrate the possibility of the expression of YqfB-type amidohydrolases in both prokaryotic and eukaryotic hosts. The small protein size and remarkable halotolerance of YqfB-type amidohydrolases are of great interest for further fundamental research and biotechnological application

Biocatalytic synthesis of asymmetric water-soluble indirubin derivatives /

A method for the synthesis of asymmetric carboxy-substituted indirubins is presented. It employs indole-5-carboxylic acid or indole-6-carboxylic acid and 2-indolinone derivatives as substrates for bacterial monooxygenase-driven enzymatic bioconversion in different bacterial hosts. This bioconversion system achieved the highest titer of monocarboxyindirubin production of up to 327 mg L−1 for 5-bromoindirubin-6′-carboxylic acid during the 16-h incubation period. The purified monocarboxyindirubins exhibited high solubility in water, up to three orders of magnitude higher than that of indirubin. In addition, several monocarboxyindirubins, namely 1-methylindirubin-5′-carboxylic acid, possess potent antiproliferative activity against different cancer cell lines. Therefore, the synthesis method for monocarboxyindirubins described herein is an efficient and environmentally friendly bioconversion system and the synthesized monocarboxyindirubins show great promise due to their high water solubility and potential antiproliferative activity

Engineering of a chromogenic enzyme screening system based on an auxiliary indole-3-carboxylic acid monooxygenase

Here, we present a proof-of-principle for a new high-throughput functional screening of metagenomic libraries for the selection of enzymes with different activities, predetermined by the substrate being used. By this approach, a total of 21 enzyme-coding genes were selected, including members of xanthine dehydrogenase, aldehyde dehydrogenase (ALDH), and amidohydrolase families. The screening system is based on a pro-chromogenic substrate, which is transformed by the target enzyme to indole-3-carboxylic acid. The later compound is converted to indoxyl by a newly identified indole-3-carboxylate monooxygenase (Icm). Due to the spontaneous oxidation of indoxyl to indigo, the target enzyme-producing colonies turn blue. Two types of pro-chromogenic substrates have been tested. Indole-3-carboxaldehydes and the amides of indole-3-carboxylic acid have been applied as substrates for screening of the ALDHs and amidohydrolases, respectively. Both plate assays described here are rapid, convenient, easy to perform, and adaptable for the screening of a large number of samples both in Escherichia coli and Rhodococcus sp. In addition, the fine-tuning of the pro-chromogenic substrate allows screening enzymes with the desired substrate specificity

Regulation of Cell Wall Plasticity by Nucleotide Metabolism in Lactococcus lactis

To ensure optimal cell growth and separation and to adapt to environmental parameters, bacteria have to maintain a balance between cell wall (CW) rigidity and flexibility. This can be achieved by a concerted action of peptidoglycan (PG) hydrolases and PG-synthesizing/modifying enzymes. In a search for new regulatory mechanisms responsible for the maintenance of this equilibrium in Lactococcus lactis, we isolated mutants that are resistant to the PG hydrolase lysozyme. We found that 14% of the causative mutations were mapped in the guaA gene, the product of which is involved in purine metabolism. Genetic and transcriptional analyses combined with PG structure determination of the guaA mutant enabled us to reveal the pivotal role of the pyrB gene in the regulation ofCWrigidity.Ourresults indicate that conversion of L-aspartate (L-Asp) to N-carbamoyl-L-aspartate by PyrB may reduce the amount of L-Asp available forPGsynthesis and thus cause the appearance of Asp/Asn-less stem peptides in PG. Such stem peptides do not form PG cross-bridges, resulting in a decrease in PG cross-linking and, consequently, reduced PG thickness and rigidity.Wehypothesize that the concurrent utilization of L-Asp for pyrimidine and PG synthesis may be part of the regulatory scheme, ensuring CW flexibility during exponential growth and rigidity in stationary phase. The fact that L-Asp availability is dependent on nucleotide metabolism, which is tightly regulated in accordance with the growth rate, provides L. lactis cells themeansto ensure optimalCWplasticity without theneedto control the expression of PG synthesis genes