Transformation of indole by methanogenic and sulfate-reducing microorganisms isolated from digested sludge

In the present study, mineralization of an aromaticN-heterocyclic molecule, indole, by microorganisms present in anaerobically digested sewage sludge was examined. The first step in indole mineralization was the formation of a hydroxylated intermediate, oxindole. The rate of transformation of indole to oxindole and its subsequent disappearance was dependent on the concentration of inoculum and indole and the incubation temperature. Methanogenesis appeared to be the dominant process in the mineralization of indole in 10% digested sludge even in the presence of high concentrations of sulfate. Enrichment of the digested sludge with sulfate as an electron acceptor allowed the isolation of a metabolically stable mixed culture of anaerobic bacteria which transformed indole to oxindole and acetate, and ultimately to methane and carbon dioxide. This mixed culture exhibited a predominance of sulfate-reducers over methanogens with more than 75% of the substrate mineralized to carbon dioxide. The investigation demonstrates that indole can be transformed by both methanogenic and sulfate-reducing microbial populations.     

The glucosinolate breakdown product indole‐3‐carbinol acts as an auxin antagonist in roots of Arabidopsis thaliana

The glucosinolate breakdown product indole‐3‐carbinol functions in cruciferous vegetables as a protective agent against foraging insects. While the toxic and deterrent effects of glucosinolate breakdown on herbivores and pathogens have been studied extensively, the secondary responses that are induced in the plant by indole‐3‐carbinol remain relatively uninvestigated. Here we examined the hypothesis that indole‐3‐carbinol plays a role in influencing plant growth and development by manipulating auxin signaling. We show that indole‐3‐carbinol rapidly and reversibly inhibits root elongation in a dose‐dependent manner, and that this inhibition is accompanied by a loss of auxin activity in the root meristem. A direct interaction between indole‐3‐carbinol and the auxin perception machinery was suggested, as application of indole‐3‐carbinol rescues auxin‐induced root phenotypes. In vitro and yeast‐based protein interaction studies showed that indole‐3‐carbinol perturbs the auxin‐dependent interaction of Transport Inhibitor Response (TIR1) with auxin/3‐indoleacetic acid (Aux/IAAs) proteins, further supporting the possibility that indole‐3‐carbinol acts as an auxin antagonist. The results indicate that chemicals whose production is induced by herbivory, such as indole‐3‐carbinol, function not only to repel herbivores, but also as signaling molecules that directly compete with auxin to fine tune plant growth and development.     

吲哚——种间及跨界信号分子新成员

吲哚作为一种典型的氮杂环芳烃化合物,在自然界中广泛存在。近年来,越来越多的研究表明吲哚具有一定的生物活性,是一种新型种间及跨界的信号分子。研究发现,吲哚不仅可以调节微生物的毒性、耐药性、生物膜形成以及群感效应等生理生化行为,调控植物生长发育和防御系统的形成过程,还能够影响动物的肠道炎症、细胞氧化压力及荷尔蒙分泌等生理健康。因此吲哚在微生物代谢、动物健康和植物生长等多个方面扮演了重要角色,具有重要的生物学及生态学双重意义。文中综述了吲哚从生物代谢到信号传递的研究历史,及其在微生物种内或种间以及微生物-动植物之间跨界的信号传导与调控作用的研究进展,旨在为揭示复杂环境中吲哚生物代谢及信号调控的生物学意义与生态学机制提供重要的理论指导。     

Wounding of Arabidopsis leaves induces indole‐3‐carbinol‐dependent autophagy in roots of Arabidopsis thaliana

In cruciferous plants insect attack or physical damage induce the synthesis of the glucosinolate breakdown product indole‐3‐carbinol, which plays a key role in the defense against attackers. Indole‐3‐carbinol also affects plant growth and development, acting as an auxin antagonist by binding to the TIR1 auxin receptor. Other potential functions of indole‐3‐carbinol and the underlying mechanisms in plant biology are unknown. Here we show that an indole‐3‐carbinol‐dependent signal induces specific autophagy in root cells. Leaf treatment with exogenous indole‐3‐carbinol or leaf‐wounding induced autophagy and inhibited auxin response in the root. This induction is lost in glucosinolate‐defective mutants, indicating that the effect of indole‐3‐carbinol is transported in the plants. Thus, indole‐3‐carbinol is not only a defensive metabolite that repels insects, but is also involved in long‐distance communication regulating growth and development in plants.     

吲哚作为细菌细胞间信号分子的研究进展

吲哚广泛存在于自然界,目前已知超过145种革兰氏阳性和阴性细菌能产生吲哚,其中包括许多病原菌。随着细菌密度感应系统及其信号分子作用机制研究的深入,吲哚已被证实是肠道病原菌如致病性大肠杆菌、迟缓爱德华氏菌、霍乱弧菌等一类细胞间重要的信号分子,并参与细菌的多种生理活动,如毒力、抗药性、生物膜形成、运动性、质粒稳定性、抗酸性、孢子产生等。更为重要的是,吲哚及其衍生物还参与协调菌群竞争,有益于人体肠道菌群平衡和免疫系统。本文在吲哚作为细胞间信号分子参与迟缓爱德华氏菌的毒力、抗药性、生物膜形成和运动性的研究基础上,对近年来吲哚作为细菌细胞间信号分子的研究进展进行了综述。随着吲哚作用机制的进一步揭示,将有助于新型抗病原菌感染策略的研发和生物工程方面的应用。     

Environmental factors affecting indole metabolism under anaerobic conditions

The influence of physiological and environmental factors on the accumulation of oxindole during anaerobic indole metabolism was investigated by high-performance liquid chromatography. Under methanogenic conditions, indole was temporarily converted to oxindole in stoichiometric amounts in media inoculated with three freshwater sediments and an organic soil. In media inoculated with methanogenic sewage sludge, the modest amounts of oxindole detected at 35 degrees C reached higher concentrations and persisted longer when the incubation temperature was decreased from 35 to 15 degrees C. Also, decreasing the concentration of sewage sludge used as an inoculum from 50 to 1% caused an increase in the accumulation of oxindole from 10 to 75% of the indole added. Under denitrifying conditions, regardless of the concentration or source of the inoculum, oxindole appeared in trace amounts but did not accumulate during indole metabolism. In addition, denitrifying consortia which previously metabolized indole degraded oxindole with no lag period. Our data suggest that oxindole accumulation under methanogenic, but not under denitrifying conditions is caused by differences between relative rates of oxindole production and destruction.     

Environmental factors affecting indole metabolism under anaerobic conditions.

The influence of physiological and environmental factors on the accumulation of oxindole during anaerobic indole metabolism was investigated by high-performance liquid chromatography. Under methanogenic conditions, indole was temporarily converted to oxindole in stoichiometric amounts in media inoculated with three freshwater sediments and an organic soil. In media inoculated with methanogenic sewage sludge, the modest amounts of oxindole detected at 35 degrees C reached higher concentrations and persisted longer when the incubation temperature was decreased from 35 to 15 degrees C. Also, decreasing the concentration of sewage sludge used as an inoculum from 50 to 1% caused an increase in the accumulation of oxindole from 10 to 75% of the indole added. Under denitrifying conditions, regardless of the concentration or source of the inoculum, oxindole appeared in trace amounts but did not accumulate during indole metabolism. In addition, denitrifying consortia which previously metabolized indole degraded oxindole with no lag period. Our data suggest that oxindole accumulation under methanogenic, but not under denitrifying conditions is caused by differences between relative rates of oxindole production and destruction.     

Structural and functional analysis of bacterial flavin-containing monooxygenase reveals its ping-pong-type reaction mechanism

A bacterial flavin-containing monooxygenase (bFMO) catalyses the oxygenation of indole to produce indigoid compounds. In the reductive half of the indole oxygenation reaction, NADPH acts as a reducing agent, and NADP(+) remains at the active site, protecting bFMO from reoxidation. Here, the crystal structures of bFMO and bFMO in complex with NADP(+), and a mutant bFMO(Y207S), which lacks indole oxygenation activity, with and without indole are reported. The crystal structures revealed overlapping binding sites for NADP(+) and indole, suggestive of a double-displacement reaction mechanism for bFMO. In biochemical assays, indole inhibited NADPH oxidase activity, and NADPH in turn inhibited the binding of indole and decreased indoxyl production. Comparison of the structures of bFMO with and without bound NADP(+) revealed that NADPH induces conformational changes in two active site motifs. One of the motifs contained Arg-229, which participates in interactions with the phosphate group of NADPH and appears be a determinant of the preferential binding of bFMO to NADPH rather than NADH. The second motif contained Tyr-207. The mutant bFMO(Y207S) exhibited very little indoxyl producing activity; however, the NADPH oxidase activity of the mutant was higher than the wild-type enzyme. It suggests a role for Y207, in the protection of hydroperoxyFAD. We describe an indole oxygenation reaction mechanism for bFMO that involves a ping-pong-like interaction of NADPH and indole.     

Diverse roles of microbial indole compounds in eukaryotic systems

Indole and its derivatives are widespread across different life forms, functioning as signalling molecules in prokaryotes and with more diverse roles in eukaryotes. A majority of indoles found in the environment are attributed to bacterial enzymes converting tryptophan into indole and its derivatives. The involvement of indoles among lower organisms as an interspecies and intraspecies signal is well known, with many reports showing that inter-kingdom interactions involving microbial indole compounds are equally important as they influence defence systems and even the behaviour of higher organisms. This review summarizes recent advances in our understanding of the functional properties of indole and indole derivatives in diverse eukaryotes. Furthermore, we discuss current perspectives on the role of microbial indoles in human diseases such as diabetes, obesity, atherosclerosis, and cancers. Deciphering the function of indoles as biomarkers of metabolic state will facilitate the formulation of diet-based treatments and open unique therapeutic opportunities.     

Indole glucosinolate breakdown and its biological effects

Most species in the Brassicaceae produce one or more indole glucosinolates. In addition to the parent indol-3-ylmethylglucosinolate (IMG), other commonly encountered indole glucosinolates are 1-methoxyIMG, 4-hydroxyIMG, and 4-methoxyIMG. Upon tissue disruption, enzymatic hydrolysis of IMG produces an unstable aglucone, which reacts rapidly to form indole-3-acetonitrile and indol-3-ylmethyl isothiocyanate. The isothiocyanate, in turn, can react with water, ascorbate, glutathione, amino acids, and other plant metabolites to produce a variety of physiologically active indole compounds. Myrosinase-initiated breakdown of the substituted indole glucosinolates proceeds in a similar manner to that of IMG. Induction of indole glucosinolate production in response to biotic stress, experiments with mutant plants, and artificial diet assays suggest a significant role for indole glucosinolates in plant defense. However, some crucifer-feeding specialist herbivores recognize indole glucosinolates and their breakdown products as oviposition and/or feeding stimulants. In mammalian diets, IMG can have both beneficial and deleterious effects. Most IMG breakdown products induce the synthesis of phase 1 detoxifying enzymes, which may in some cases prevent carcinogenesis, but in other cases promote carcinogenesis. Recent advances in indole glucosinolate research have been fueled by their occurrence in the well-studied model plant Arabidopsis thaliana. Knowledge gained from genetic and biochemical experiments with A. thaliana can be applied to gain new insight into the ecological and nutritional properties of indole glucosinolates in other plant species.     

Physiological Effects of a Constitutive Tryptophanase in Bacillus alvei.

Hoch, J. A. (University of Illinois, Urbana), and R. D. DeMoss. Physiological effects of a constitutive tryptophanase in Bacillus alvei. J. Bacteriol. 90:604-610. 1965.-Tryptophanase synthesis in B. alvei is not under the control of tryptophan and is not subject to catabolite repression. Exogenously supplied tryptophan was converted to indole by tryptophanase, and was excreted into the culture medium. The amount of indole excreted was dependent upon the concentration of tryptophan supplied. At intermediate levels of tryptophan (5 to 15 mug/ml), the excreted indole was completely reutilized by the cell, in contrast to the result with higher levels. Indole reutil zation was shown to be dependent upon a functional tryptophan synthetase. In the absience of exogenous tryptophan, indole was excreted into the culture medium at an earlier physiological age. The early indole was shown not to be a consequence of tryptophanase action. The early indole accompanied uniformly the normal process of tryptophan biosynthesis, and the fission of indole-3-glycerol phosphate was suggested as the origin of the excreted indole.     

Role of multiple efflux pumps in Escherichia coli in indole expulsion

Escherichia coli chromosome encodes several multidrug transporters. Despite their protective function against antibacterial agents, the specific physiological actions of these transporters are not fully understood. E. coli produces indole, a metabolite of tryptophan, under physiological conditions. Defined inactivation of the acrEF gene, the product of which is known as an energy-dependent multiple drug efflux pump, decreased indole excretion while reintroduction of the acrEF gene restored it. A DeltaacrEF mutant accumulated more intracellular indole than the parent. This mutant was more susceptible to the growth-inhibitory effect of indole than the parent. These results indicate that the AcrEF system plays a significant role in indole efflux.     

The use of 6-(difluoromethyl)indole to study the activation of indole by tryptophan synthase

6-(Difluoromethyl)indole has been characterized and developed as a probe for the turnover of indole by the bifunctional enzyme, tryptophan synthase (alpha 2 beta 2). The neutral form of the indolyl species undergoes a slow and spontaneous hydrolysis to produce 6-formylindole with a rate constant (k1) of 0.0089 +/- 0.0001 min-1. The overall rate is independent of pH in the range of 3.5-10.5. Above pH 10.5, the observed rate increases are due to the high reactivity of the anionic form of the indole; deprotonation at N-1 accelerates hydrolysis by 10(4)-fold (k2, 97 +/- 2 min-1). The magnitude of this effect provides a technique for detecting the formation or stabilization of the anionic form of indole. 6-(Difluoromethyl)indole is recognized and processed by the beta subunit of tryptophan synthase. Selective inactivation of the beta subunit prevents enzymatic processing of 6-(difluoromethyl)indole. Chromatographic isolation and mass spectral analysis has identified 6-(difluoromethyl)tryptophan as the sole turnover product of the indolyl substrate. The lack of enzyme-promoted dehalogenation does not exclude the formation of an indole anion during turnover but rather the data suggest that rapid carbon-carbon bond formation (greater than 5300 min-1) prevents the accumulation of this anion.     

Conformational complexity of melatonin in water and methanol

The magnetic circular dichroism (MCD) spectra of melatonin in water and methanol solutions is compared to the MCD spectra of indole and five melatonin conformations observed in low temperature jet spectroscopy. Based on a survey of indole compounds using Slater type orbitals-6G(d,p) and B3LYP/6-31G(d) energies, and CNDO/S-D calculations of MCD spectral bands, a dominant structure with a water molecule bridging the amide-keto oxygen and indole Nz-H atoms is proposed as the best fit for the MCD of aqueous melatonin. In methanol an additional band appears at 310 nm which is supported only by solvated structures in which the alkyl-amide arm is extended away from the indole moiety.     

Excitation of indole analogs by phagocytosing leukocytes

The system suspended with phagocytosing leukocytes and related system produce weak light which could be greatly amplified by indole analogs with plain fatty acids at 3 position. Main emitting species in indole-3-acetic acid or indole-3-propionic acid-sensitized system was analyzed spectrometrically in the dark and ascribed to the transition of an excited indole compound in triplet state to its ground state. Such an excited species would be generated by the oxidative way of the indole analogs but not through the dioxetane structure of 2 and 3 positions on indole ring.     

Inhibition of amyloid fibrillation of lysozyme by indole derivatives--possible mechanism of action

Amyloid aggregation of polypeptides is related to a growing number of pathologic states known as amyloid disorders. There is a great deal of interest in developing small molecule inhibitors of the amyloidogenic processes. In the present article, the inhibitory effects of some indole derivatives on amyloid fibrillation of hen egg white lysozyme (HEWL) are reported. Acidic pH and high temperatures were used to drive HEWL towards amyloid formation. A variety of techniques, ranging from thioflavin T fluorescence and Congo red absorbance assays to far-UV CD and transmission electron microscopy, were employed to characterize the HEWL fibrillation process. Among the indole derivatives tested, indole 3-acetic acid, indole 3-carbinol and tryptophol had the most inhibitory effects on amyloid formation, indole and indole 3-propionic acid gave some inhibition, and indole aldehyde and tryptophan showed no significant inhibition. Although indoles did not protect the HEWL native state from conformational changes, they were effective in diminishing HEWL amyloid fibril formation, delaying both the nucleation and elongation phases. Disaggregation of previously formed HEWL amyloid fibrils was also enhanced by indole 3-acetic acid. Various medium conditions, such as the presence of different anions and alcoholic cosolvents, were explored to gain an insight into possible mechanisms. These observations, taken together, suggest that the indole ring is likely to play the main role in inhibition and that the side chain hydroxyl group may contribute positively, in contrast to the side chain carbonyl and intervening methylene groups.     

p-dimethylaminocinnamaldehyde derivatization for colorimetric detection and HPLC-UV/vis-MS/MS identification of indoles

Cytochrome P450 2A13 (CYP2A13) is a lung specific enzyme known to activate the potent tobacco procarcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) into two carcinogenic metabolites. CYP2A13 has been crystallized and X-ray diffraction experiments illuminated the structure of this enzyme, but with an unknown ligand present in the enzyme active site. This unknown ligand was suspected to be indole but a selective method had to be developed to differentiate among indole and its metabolites in the protein sample. We successfully modified a microbiological colorimetric assay to spectrophotometrically differentiate between indole and a number of possible indole metabolites in nanomolar concentrations by derivatization with p-dimethylaminocinnamaldehyde (DMACA). Further differentiation of indoles was made by mass spectrometry (HPLC-UV/vis-MS/MS) utilizing the chromophore generated in the DMACA conjugation as a UV signature for HPLC detection. The ligand in the crystallized protein was identified as unsubstituted indole, which facilitated refinement of two alternate conformations in the CYP2A13 crystal structure active site.     

1,2-Disubstituted indole, azaindole and benzimidazole derivatives possessing amine moiety: a novel series of thrombin inhibitors

A novel series of 1,2-disubstituted indole, azaindole and benzimidazole derivatives possessing an amine moiety was identified as thrombin inhibitors. An indole with basic diamine moieties (12a) was the most potent thrombin inhibitor in the series with Kass= 197 x 10(6) L/mol.     

Microbial hydroxylation of indole to 7-hydroxyindole by Acinetobacter calcoaceticus strain 4-1-5

A screening study yielded Acinetobacter calcoaceticus strain 4-1-5, which is capable of hydroxylating indole to 7-hydroxyindole. Strain 4-1-5 grew on terephthalate as the sole source of carbon and energy and hydroxylated indole to 7-hydroxyindole by cometabolism of indole using terephthalate as cosubstrate. Strain 4-1-5 produced 0.574 mM of 7-hydroxyindole at 2.38 mM indole in 24 h with the cell growth.