Project description:Narcosis or baseline toxicity is the inert toxicity of hydrophobic compounds, supposed to take place at the level of the cellular membranes. Based on the linear relationship between the toxicity (logEC50) and the hydrophobicity (logKow), class I and II narcotizing compounds are recognized, in which the latter group is assumed to exert additional toxic mechanisms by hydrogen bond donor acidity by their polar groups. Chlorinated anilines, which occur often in the environment as degradation products of certain pesticides , are considered to be narcotizing compounds. In this study the transcriptional responses of the soil arthropod Folsomia candida are investigated upon exposure to a series of anilines with increasing chlorination. A discrimination between class1 and class2 narcotizing compound is being made.

Project description:Parallel Artificial Membrane Permeability is an in vitro surrogate to determine the permeability of drugs across cellular membranes. PAMPA at pH 5 was experimentally determined in a dataset of 5,473 unique compounds by the NIH-NCATS. 50% of the dataset was used to train a classifier (SVM) to predict the permeability of new compounds, and validated on the remaining 50% of the data, rendering an AUC = 0.88. The Peff was converted to logarithmic, log Peff value lower than 2.0 were considered to have low to moderate permeability, and those with a value higher than 2.5 were considered as high-permeability compounds. Model Type: Predictive machine learning model. Model Relevance: Predicting compound permeability across cellular membranes. Model Encoded by: Pauline (Ersilia) Metadata Submitted in BioModels by: Zainab Ashimiyu-Abdusalam Implementation of this model code by Ersilia is available here: https://github.com/ersilia-os/eos81ew

Project description:Narcosis or baseline toxicity is the inert toxicity of hydrophobic compounds, supposed to take place at the level of the cellular membranes. Based on the linear relationship between the toxicity (logEC50) and the hydrophobicity (logKow), class I and II narcotizing compounds are recognized, in which the latter group is assumed to exert additional toxic mechanisms by hydrogen bond donor acidity by their polar groups. Chlorinated anilines, which occur often in the environment as degradation products of certain pesticides , are considered to be narcotizing compounds. In this study the transcriptional responses of the soil arthropod Folsomia candida are investigated upon exposure to a series of anilines with increasing chlorination. A discrimination between class1 and class2 narcotizing compound is being made. Twenty-three day old Folsomia candida were exposed in LUFA 2.2 standard soil for two days to the EC50 concentrations of the following compounds: aniline, 4-chloroaniline, 3.5-dichloroaniline, 2,3,4-trichloroaniline, 2,3,5,6-tetrachloroaniline, pentachloroaniline and 1,2,3,4-tetrachlorobenzene.1,2,3,4-tetrachlrobenzene was included in the experimental design as a posiitive control of a narcotic class 1 compound. Four biological replicates were used for every treatment and a dye swap was used with the Cy3/Cy5 labels. This resulted in 32 samples which were analysed in 16 hybridisations executed in an interwoven loop design. The solvent (for spiking the soil) control was used as the reference treatment in the data analysis.

Project description:An improved understanding of the genome-wide regulation of natural compound biosynthesis in bacterial producers may accelerate the discovery of novel biologically active molecules and facilitate their production. To this end, we have investigated the time course of genome-wide transcription in the myxobacterium Sorangium sp. So ce836 in relation to its production of natural compounds. Time-resolved RNA sequencing revealed the dynamic temporal variation of transcriptional activity, indicating that core biosynthesis genes from 48 biosynthetic gene clusters (BGCs; 92% of all BGCs encoded in the genome) were actively transcribed at specific time points in a batch culture. The majority (80%) of polyketide synthase and nonribosomal peptide synthetase genes displayed distinct peaks of transcription during exponential bacterial growth. Strikingly, these surges in BGC transcriptional activity were associated with boosts in the production of known natural compounds, indicating that their biosynthesis was crucially regulated at the transcriptional level. In contrast, BGC read counts from single time points had limited predictive value about biosynthetic activity, since transcription levels varied >100-fold among BGCs with detected natural products. Taken together, our time-course data provided unique insights into the dynamics of natural compound biosynthesis and its regulation in a wild-type myxobacterium, challenging the commonly cited notion of preferential BGC expression under meager conditions for bacterial growth. The close association between BGC transcription and compound production suggested that the molecular manipulation of transcriptional activity may be a viable strategy to increase compound yields from myxobacterial producer strains, warranting increased efforts to develop genetic engineering tools for these organisms.

Project description:In this study, the researchers isolated a colorless waxy solid from the chloroform extract of Allium stipitatum as Compound 1. They demonstrated compound 1 is a potent bactericidal agent against nonreplicating Mycobacterium tuberculosis. Using microarray technology the authors report gene expression profiles in cells treated with either 2, 5, or 10 ug/ml of compound 1 or an equivalent amount of DMSO as control for 6 h. Gene expression studies revealed that transcriptional profiles elicited in response to compound 1 were similar to the profiles generated during treatment of cells with compounds such as menadione and 8-quinolinol that result in oxidative stress. They included the thioredoxin system components encoded by trxB2 and trxC as well as several genes associated with the heat shock response such as clpB, sigH, dnaJ, dnaK, hsp, Rv0331, Rv3463, Rv3054c, and Rv1334-Rv1335. These results suggest that compound 1 possibly generates damaged proteins and other oxidative stress signals as part of its mechanism of action. The following is the full abstract of this published study. O'Donnell G, et al. (2009) J Nat Prod 72(3):360-365 From Allium stipitatum, three pyridine-N-oxide alkaloids (1-3) possessing disulfide functional groups were isolated. The structures of these natural products were elucidated by spectroscopic means as 2-(methyldithio)pyridine-N-oxide (1), 2-[(methylthiomethyl)dithio]pyridine-N-oxide (2), and 2,2'-dithio-bis-pyridine-N-oxide (3). The proposed structure of 1 was confirmed by synthetic S-methylthiolation of commercial 2-thiopyridine-N-oxide. Compounds 1 and 2 are new natural products, and 3 is reported for the first time from an Allium species. All compounds were evaluated for activity against fast-growing species of Mycobacterium, methicillin-resistant Staphylococcus aureus, and a multidrug-resistant (MDR) variants of S. aureus. Compounds 1 and 2 exhibited minimum inhibitory concentrations (MICs) of 0.5-8 mug/ml against these strains. A small series of analogues of 1 were synthesized in an attempt to optimize antibacterial activity, although the natural product had the most potent in vitro activity. In a whole-cell assay at 30 mug/ml, 1 was shown to give complete inhibition of the incorporation of (14)C-labeled acetate into soluble fatty acids, indicating that it is potentially an inhibitor of fatty acid biosynthesis. In a human cancer cell line antiproliferative assay, 1 and 2 displayed IC(50) values ranging from 0.3 to 1.8 muM with a selectivity index of 2.3 when compared to a human somatic cell line. Compound 1 was evaluated in a microarray analysis that indicated a similar mode of action to menadione and 8-quinolinol by interfering with the thioredoxin system and up-regulating the production of various heat shock proteins. This compound was also assessed in a mouse model for in vivo toxicity. A dose response design type examines the relationship between the size of the administered dose and the extent of the response of the organism(s). Compound Based Treatment: Allium stipitatum (garlic) extract dose_response_design

Project description:Catechol-containing natural products are common constituents of foods, drinks, and drugs. Natural products carrying this motif are often associated with beneficial biological effects such as anticancer activity and neuroprotection. However, the molecular mode of action behind these properties is poorly understood. Here, we apply a mass spectrometry-based competitive chemical proteomics approach to elucidate the target scope of catechol-containing bioactive molecules from diverse foods and drugs. Inspired by the protein reactivity of catecholamine neurotransmitters, we designed and synthesised a broadly reactive minimalist catechol chemical probe based on dopamine. Initial labelling experiments in live human cells demonstrated broad protein binding by the probe, which was largely outcompeted by its parent compound dopamine. Next, we investigated the competition profile of a selection of biologically relevant catechol-containing compounds. With this approach, we characterised the protein reactivity and the target scope of dopamine and ten catechols. Strikingly, proteins associated with the endoplasmic reticulum (ER) were among the main targets. ER stress assays in the presence of reactive catechols revealed an activation of the IRE1-branch of the unfolded protein response (UPR), whereas unreactive catechols had no effect. As the UPR is an intriguing oncology target, this provides a possible explanation of the health-promoting effects attributed to many catechol natural products.

Project description:The chemical diversification of natural products provides a robust and general method for creation of stereochemically complex and structurally diverse small molecules. The resulting compounds have physicochemical traits different from those in most screening collections, and as such are a rich source for biological discovery. Herein, we subject the terpene natural product pleuromutilin to reaction sequences focused on creating ring system diversity in few synthetic steps. This effort resulted in the synthesis of multiple compounds with previously unreported ring systems, providing a set of novel structurally diverse and highly complex compounds suitable for screening in a variety of different settings. Biological evaluation of these compounds identified the novel compound ferroptocide, a compound that rapidly and robustly induces ferroptotic death of cancer cells. Target identification efforts and CRISPR KO studies reveal that ferroptocide is an inhibitor of thioredoxin, a key component of thioredoxin antioxidant system in the cell. Ferroptocide shows the ability to positively modulate the immune system in a murine model of breast cancer and will be a useful tool to study the ability of pro-ferroptotic agents to synergize with the immune system for treatment of cancer.

Project description:We conducted a comprehensive screening of bioactive compounds sourced from natural products, specifically targeting those capable of inducing apoptosis while inhibiting tyrosine kinase activity. Our investigation encompassed a diverse range of compounds, including pure compounds, compound mixtures, and peptides, all evaluated within the A549 cell line. To delve into the underlying molecular mechanisms, we employed phosphoproteomics analysis, which enabled us to comprehensively assess the impact of these bioactive compounds on cellular pathways. Through labeling digested proteins with distinct isobaric tags, we meticulously examined the cellular response to each compound. In our experimental design, we included two established chemical drugs, Afatinib and Osimertinib, serving as positive controls. These drugs, both kinase inhibitors utilized in cancer treatment, operate via distinct mechanisms and target different kinases. By comparing the effects of our test compounds with these controls, we aimed to elucidate their potential therapeutic relevance and mechanisms of action. Among the compounds examined were extracts from Phallus indusiatus and Fomes rimosus (Berk.) Cooke, as well as specific compounds like Chamuangone, Cannabigerol (CBG), Cannabidiol (CBD), and NP1-cyclic peptide

Project description:The chemical diversification of natural products provides a robust and general method for creation of stereochemically rich and structurally diverse small molecules. The resulting compounds have physicochemical traits different from those in most screening collections, and as such are an excellent source for biological discovery. Herein, we subject the diterpene natural product pleuromutilin to reaction sequences focused on creating ring system diversity in few synthetic steps. This effort resulted in a collection of compounds with previously unreported ring systems, providing a novel set of structurally diverse and highly complex compounds suitable for screening in a variety of different settings. Biological evaluation identified the novel compound ferroptocide, a small molecule that rapidly and robustly induces ferroptotic death of cancer cells. Target identification efforts and CRISPR knockout studies reveal that ferroptocide is an inhibitor of thioredoxin, a key component of the antioxidant system in the cell. Ferroptocide positively modulates the immune system in a murine model of breast cancer and will be a useful tool to study the utility of pro-ferroptotic agents for treatment of cancer.

Project description:Finding the targets of natural products is of key importance in both chemical biology and drug discovery, and deconvolution of cofactor interactomes contribute to the functional annotation of the proteome. Identifying the proteins that underlie natural compound activity in phenotypic screens help to validate the respective targets and, potentially, expand the druggable proteome. Here, we present a generally applicable protocol for the photoactivated immobilisation of unmodified and microgram quantities of natural products on diazirine-decorated beads and their use for systematic affinity-based proteome profiling. We show that amongst 31 molecules of very diverse reported activity and biosynthetic origin, 25 could indeed be immobilised. Dose-response competition binding experiments using lysates of human or bacterial cells followed by quantitative mass spectrometry recapitulated <100 µM targets of 9 molecules. Among them, immobilisation of coenzyme A produced a tool to interrogate proteins containing a HotDog domain. Surprisingly, immobilisation of the cofactor flavin adenine dinucleotide (FAD) led to the identification of nanomolar interactions with dozens of RNA-binding proteins.