Project description:Recent development of benzoxaborole-based chemistry gave rise to a collection of compounds with great potential in targeting diverse infectious diseases, including human African Trypanosomiasis (HAT), a devastating neglected tropical disease. However, further medicinal development is largely restricted by a lack of insight into mechanism of action (MoA) in pathogenic kinetoplastids. We adopted a multidisciplinary approach, combining a high-throughput forward genetic screen with functional group focused chemical biological, structural biology and biochemical analyses, to tackle the complex MoAs of benzoxaboroles in Trypanosoma brucei. We describe an oxidative enzymatic pathway composed of host semicarbazide-sensitive amine oxidase and a trypanosomal aldehyde dehydrogenase TbALDH3. Two sequential reactions through this pathway serve as the key underlying mechanism for activating a series of 4-aminomethylphenoxy-benzoxaboroles as potent trypanocides; the methylamine parental compounds as pro-drugs are transformed first into intermediate aldehyde metabolites, and further into the carboxylate metabolites as effective forms. Moreover, comparative biochemical and crystallographic analyses elucidated the catalytic specificity of TbALDH3 towards the benzaldehyde benzoxaborole metabolites as xenogeneic substrates. Overall, this work proposes a novel drug activation mechanism dependent on both host and parasite metabolism of primary amine containing molecules, which contributes a new perspective to our understanding of the benzoxaborole MoA, and could be further exploited to improve the therapeutic index of antimicrobial compounds.

Project description:Approved drugs are invaluable tools to study biochemical pathways and further characterization of these compounds may lead to repurposing of single drugs or combinations. Here, we describe a collection of 308 small molecules representing the diversity of structures and molecular targets of all FDA-approved chemical entities. The CeMM Library of Unique Drugs (CLOUD) covers prodrugs and active forms at pharmacologically relevant concentrations and is ideally suited for combinatorial studies. We screened pairwise combinations of CLOUD drugs for impairment of cancer cell viability and discovered the synergistic interaction between flutamide and phenprocoumon (PPC). The combination of these two drugs modulates the stability of the androgen receptor (AR) and resensitizes AR mutant prostate cancer cells to flutamide. Mechanistically, we show that the AR is a substrate for γ-carboxylation, a post-translational modification inhibited by PPC. Collectively, our data suggest that PPC might be repurposed to tackle resistance to antiandrogens in prostate cancer patients.

Project description:Methyloversatilis universalis FAM5 utilizes single carbon compounds such as methanol or methylated amines as a sole source of carbon and energy. Expression profiling reveals distinct sets of genes altered during growth on methanol vs methylamine. Growth on methanol results in activation of mdh2 and a number of known accessory proteins. As expected, all genes for N-methylglutamate pathway were induced during growth on methylated amine. Among other functions, responding to a switch from methanol to methylated amines, are a heme-containing amine dehydrogenase (QHNDH), a PQQ-dependent methanol dehydrogenase homologue, a distant homologue of formaldehyde activating enzyme (fae3), molybdenum containing formate dehydrogenase, a set of transporters homologues to urea/ammonium transporters and amino-acid permeases. Genes encoding the PQQ-dependent methanol dehydrogenase and associated cytochrome, the enzymes from the assimilatory H4F-dependent pathway, and the tungsten-containing aldehyde oxidoreductase were down-regulated during growth on methylamine. Genes essential for carbon assimilation (serine cycle) and H4MTP-pathway for formaldehyde oxidation show similar level of expression on both C1-carbon sources. Phenotypic analysis of mutants lacking functional QHNDH had no growth defect on C1-compounds. M. universalis FAM5 strain with the methylene-tetrahydrofolate dehydrogenase lesion, a key enzyme of the H4-folate pathway, were not able to use any C1-compound, methanol or methylated amines. Methyloversatilis universalis FAM5 possesses three homologs of the formaldehyde activating enzymes. The relative expression of two of the formaldehyde activating enzyme (fae1) and fae2 did not change after the shift from methanol to methylamine growth. The relative expression of the third homologs, fae3, was significantly upregulated by methylamine. Single and double fae 2 and fae 3 mutants display similar to wild type growth M-BM- on methanol or methylamine. Strains lacking fae1 lost the ability to grow on both C1-compounds. However upon incubation on methylated amines the fae1-mutant produce revertants (fae1R ). The revertant strains displayed an impaired growth on methylamine but were not able to use methanol. Double mutations in fae1RM-BM- / fae3 or fae1R/fae2 and triple mutant fae1R/fae2/fae3 showed similar to fae1R phenotype. The metabolic pathways for utilization methanol and methylamine in Methyloversatilis universalis FAM5 are reconstructed. Methyloversatilis universalis FAM5 grown on methanol and methylamine with two biologial replicates for each condition. RNA-Seq was used for transcriptomics.

Project description:Toxic inhibitory compounds from lignocellulose pretreatment are the major obstacle to achieve high bioconversion efficiency in biorefinery fermentations. This study shows a unique glucose oxidation catalysis of Gluconobacter oxydans with its gluconic acid productivity free of inhibitor disturbance. The microbial experimentations and the transcriptome analysis revealed that both the activity of the membrane-bound glucose dehydrogenase (mGDH) and the transcription level of the genes in periplasmic glucose oxidation respiratory chain of G. oxydans were essentially not affected under the existence of inhibitory compounds. G. oxydans also rapidly converted furan and phenolic aldehyde inhibitors into the less toxic alcohols or acids. The synergy of the robust periplasmic glucose oxidation and the rapid inhibitor conversion of G. oxydans significantly elevated the efficiency of the oxidative fermentation in lignocellulose hydrolysate. The corresponding genes responsible for the conversion of furan and phenolic aldehyde inhibitors were also mined by DNA microarrays. The synergistic mechanism of G. oxydans provided an important option of metabolic modification for enhancing inhibitor tolerance of general fermentation strains.

Project description:Choline analogs represent a novel class of antimalarial compounds with strong potency against drug-sensitive and resistant P. falciparum. Although, these drugs are presumed to target proteins within lipid biosynthesis pathways; their complete mechanism of action and the parasite’s compensatory response remain to be elucidated. We have applied transcriptional profiling to characterize the global response to the choline analog T4 during the P. falciparum intraerythrocytic life cycle Keywords: Trascriptome analysis of Plasmodium falciparum in response to external stimuli using the affymetrix platform GPL3575

Project description:Methyloversatilis universalis FAM5 utilizes single carbon compounds such as methanol or methylated amines as a sole source of carbon and energy. Expression profiling reveals distinct sets of genes altered during growth on methanol vs methylamine. Growth on methanol results in activation of mdh2 and a number of known accessory proteins. As expected, all genes for N-methylglutamate pathway were induced during growth on methylated amine. Among other functions, responding to a switch from methanol to methylated amines, are a heme-containing amine dehydrogenase (QHNDH), a PQQ-dependent methanol dehydrogenase homologue, a distant homologue of formaldehyde activating enzyme (fae3), molybdenum containing formate dehydrogenase, a set of transporters homologues to urea/ammonium transporters and amino-acid permeases. Genes encoding the PQQ-dependent methanol dehydrogenase and associated cytochrome, the enzymes from the assimilatory H4F-dependent pathway, and the tungsten-containing aldehyde oxidoreductase were down-regulated during growth on methylamine. Genes essential for carbon assimilation (serine cycle) and H4MTP-pathway for formaldehyde oxidation show similar level of expression on both C1-carbon sources. Phenotypic analysis of mutants lacking functional QHNDH had no growth defect on C1-compounds. M. universalis FAM5 strain with the methylene-tetrahydrofolate dehydrogenase lesion, a key enzyme of the H4-folate pathway, were not able to use any C1-compound, methanol or methylated amines. Methyloversatilis universalis FAM5 possesses three homologs of the formaldehyde activating enzymes. The relative expression of two of the formaldehyde activating enzyme (fae1) and fae2 did not change after the shift from methanol to methylamine growth. The relative expression of the third homologs, fae3, was significantly upregulated by methylamine. Single and double fae 2 and fae 3 mutants display similar to wild type growth  on methanol or methylamine. Strains lacking fae1 lost the ability to grow on both C1-compounds. However upon incubation on methylated amines the fae1-mutant produce revertants (fae1R ). The revertant strains displayed an impaired growth on methylamine but were not able to use methanol. Double mutations in fae1R / fae3 or fae1R/fae2 and triple mutant fae1R/fae2/fae3 showed similar to fae1R phenotype. The metabolic pathways for utilization methanol and methylamine in Methyloversatilis universalis FAM5 are reconstructed.

Project description:This dataset supports a study redefining the functional scope of the Aldehyde Dehydrogenase (ALDH) superfamily as dual-function Alcohol and Aldehyde Dehydrogenases (AALDH). While ALDH2 is classically known for acetaldehyde detoxification, we demonstrate through biochemical and cellular approaches that it possesses robust, intrinsic alcohol dehydrogenase activity.

Project description:Fungal infections are a serious health problem in the clinic especially in the immunocompromised patient. Disease ranges from widespread superficial vulvovaginal infections to life-threatening systemic candidiasis. Especially for systemic mycoses only a limited arsenal of antimycotica are available, including azoles, polyenes, echinocandines and amphothericin B. Due to emerging resistance to standard therapy and significant side effects for some antimycotica there is a medical need for new antifungals in the clinic and general practice. In order to expand the arsenal of compounds with antifungal activities we screened compound libraries, including combinatorial libraries as well as more than 30 000 pure compounds derived from organic synthesis for antimycotic activity. In total more than 100 000 compounds were screened using an innovative AS (activity-selectivity) assay analyzing both the antifungal activity and the compatability with human cells at the same time. One promising hit, a Benzimidazol-2-yl-alkylamine derivative, was developed in a series of lead compounds showing potent antifungal activity. ((1S)-1-[1-(3-chlorobenzyl)-1H-benzimidazol-2-yl]-2-methylpropyl-amine) (EMC120B12) showed the highest antifungal activity and best compatability with human cells in several cell culture models and against a number of different yeasts and clinical isolates. Transcriptional profiling indicates that the newly discovered compound is a potential inhibitor of the ergosterol-pathway. In total, three biological replicates were performed. All experiments were performed as dye swaps. Thus, in total six arrays have been hybridzed. Hybridization experiments included an untreated reference sample and a sample of cells treated with ((1S)-1-[1-(3-chlorobenzyl)-1H-benzimidazol-2-yl]-2-methylpropyl-amine) (EMC120B12). The array included one technical replicate of each probe.

Project description:Biopsies are underrated and underused and our goal was to demonstrate that their inherent expression proteomic pattern could give them an added value for diagnosis. As proof of concept, we used as model hepatocellular adenomas (HCA), well characterized benign liver tumors. From a collection of 260 cases, we selected 55 typical cases to build the first HCA proteomic database. Biopsies proteomic patterns allowed HCA classification, even for complex cases. In addition, these data gave access to a malignancy pattern identifying the HCA transformation. This pioneering work proposes a proteomic based machine learning tool, operational on fixed biopsies, to improve HCA diagnosis and therefore patient’s management.

Project description:Biopsies are underrated and underused and our goal was to demonstrate that their inherent expression proteomic pattern could give them an added value for diagnosis. As proof of concept, we used as model hepatocellular adenomas (HCA), well characterized benign liver tumors. From a collection of 260 cases, we selected 55 typical cases to build the first HCA proteomic database. Biopsies proteomic patterns allowed HCA classification, even for complex cases. In addition, these data gave access to a malignancy pattern identifying the HCA transformation. This pioneering work proposes a proteomic based machine learning tool, operational on fixed biopsies, to improve HCA diagnosis and therefore patient’s management.