Project description:Multi-layered omics technologies can help define relationships between genetic factors, biochemical processes and phenotypes thus extending research of monogenic diseases beyond identifying their cause. We implemented a multi-layered omics approach for the inherited metabolic disorder methylmalonic aciduria. We performed whole genome sequencing, transcriptomic sequencing, and mass spectrometry-based proteotyping from matched primary fibroblast samples of 230 individuals (210 affected, 20 controls) and related the molecular data to 105 phenotypic features. Integrative analysis identified a molecular diagnosis for 84% (179/210) of affected individuals, the majority (150) of whom had pathogenic variants in methylmalonyl-CoA mutase (MMUT). Untargeted integration of all three omics layers revealed dysregulation of TCA cycle and surrounding metabolic pathways, a finding that was further supported by multi-organ metabolomics of a hemizygous Mmut mouse model. Stratification by phenotypic severity indicated downregulation of oxoglutarate dehydrogenase and upregulation of glutamate dehydrogenase in disease. This was supported by metabolomics and isotope tracing studies which showed increased glutamine-derived anaplerosis. We further identified MMUT to physically interact with both, oxoglutarate dehydrogenase and glutamate dehydrogenase providing a mechanistic link. This study emphasizes the utility of a multi-modal omics approach to investigate metabolic diseases and highlights glutamine anaplerosis as a potential therapeutic intervention point in methylmalonic aciduria.

Project description:Multi-layered omics technologies can help define relationships between genetic factors, biochemical processes and phenotypes thus extending research of monogenic diseases beyond identifying their cause. We implemented a multi-layered omics approach for the inherited metabolic disorder methylmalonic aciduria. We performed whole genome sequencing, transcriptomic sequencing, and mass spectrometry-based proteotyping from matched primary fibroblast samples of 230 individuals (210 affected, 20 controls) and related the molecular data to 105 phenotypic features. Integrative analysis identified a molecular diagnosis for 84% (179/210) of affected individuals, the majority (150) of whom had pathogenic variants in methylmalonyl-CoA mutase (MMUT). Untargeted integration of all three omics layers revealed dysregulation of TCA cycle and surrounding metabolic pathways, a finding that was further supported by multi-organ metabolomics of a hemizygous Mmut mouse model. Stratification by phenotypic severity indicated downregulation of oxoglutarate dehydrogenase and upregulation of glutamate dehydrogenase in disease. This was supported by metabolomics and isotope tracing studies which showed increased glutamine-derived anaplerosis. We further identified MMUT to physically interact with both, oxoglutarate dehydrogenase and glutamate dehydrogenase providing a mechanistic link. This study emphasizes the utility of a multi-modal omics approach to investigate metabolic diseases and highlights glutamine anaplerosis as a potential therapeutic intervention point in methylmalonic aciduria.

Project description:Multi-layered omics technologies can help define relationships between genetic factors, biochemical processes and phenotypes thus extending research of monogenic diseases beyond identifying their cause. We implemented a multi-layered omics approach for the inherited metabolic disorder methylmalonic aciduria. We performed whole genome sequencing, transcriptomic sequencing, and mass spectrometry-based proteotyping from matched primary fibroblast samples of 230 individuals (210 affected, 20 controls) and related the molecular data to 105 phenotypic features. Integrative analysis identified a molecular diagnosis for 84% (179/210) of affected individuals, the majority (150) of whom had pathogenic variants in methylmalonyl-CoA mutase (MMUT). Untargeted integration of all three omics layers revealed dysregulation of TCA cycle and surrounding metabolic pathways, a finding that was further supported by multi-organ metabolomics of a hemizygous Mmut mouse model. Stratification by phenotypic severity indicated downregulation of oxoglutarate dehydrogenase and upregulation of glutamate dehydrogenase in disease. This was supported by metabolomics and isotope tracing studies which showed increased glutamine-derived anaplerosis. We further identified MMUT to physically interact with both, oxoglutarate dehydrogenase and glutamate dehydrogenase providing a mechanistic link. This study emphasizes the utility of a multi-modal omics approach to investigate metabolic diseases and highlights glutamine anaplerosis as a potential therapeutic intervention point in methylmalonic aciduria.

Project description:Omics approaches have succeeded in understanding the boosted productivity of natural products by industrial high-producing microorganisms. Here, with the updated genome sequence and transcriptomic profiles derived from next-generation high throughput sequencing, we exploited comparative omics analysis to further enhance the biosynthesis of erythromycin in an industrial overproducer, Saccharopolyspora erythraea HL3168 E3. By comparing the genome of E3 with the wild type NRRL23338, we identified large deletions of 30 kilobases in total located inside coding sequences and 255 single nucleotide polymorphisms over the whole genome of E3. A large amount of genomic variation was observed in genes responsible for pathways which supply precursors, cofactors and signals for the biosynthesis of erythromycin. Transcriptional analysis revealed 2-oxoglutarate and L-glutamine/L-glutamate as reporter metabolites to distinguish the two strains. Around the node of 2-oxoglutarate, also genomic mutations were observed. Furthermore, the transcriptomic data suggested that genes involved in the biosynthesis of erythromycin were significantly up-regulated constantly, whereas some genes in the biosynthesis clusters of other secondary metabolites contained nonsense mutations and were expressed at extremely low levels. Based on the omics analysis, readily available strategies were proposed to engineer E3 by simultaneously overexpressing sucB (coding for 2-oxoglutarate dehydrogenase E2 component) and sucA (coding for 2-oxoglutarate dehydrogenase E1 component), which increased the erythromycin titer by 45% compared to E3 in batch culture. This work provides more promising molecular targets to engineer for enhancement of erythromycin production.

Project description:Metabolic dysregulation, including perturbed glutamine-glutamate homeostasis, is common in atherosclerotic cardiovascular disease. Here, we reveal that modulation of glutaminolysis or glutamate availability in culture media is critical for smooth muscle cell line (MOVAS) phenotypic switching. Cells were treated for 24 hours with glutaminase inhibitors (50mM DON, Sigma-SML0601) in presence or absence of 2mM glutamate suplementation (Gibco-35050061). High-throughput transcriptional profiling revealed that modulation of glutamine and glutamate homeostasis impacted genes involved in protein and extracellular matrix organization, cell motility and microtubule. Thus, we uncovered a novel role for glutamine metabolism in the phenotypic switch in SMCs, a hallmark of vascular remodelling.

Project description:Metabolic dysregulation, including perturbed glutamine-glutamate homeostasis, is common in atherosclerotic cardiovascular disease. Here, we reveal that modulation of glutaminolysis or glutamate availability in culture media is critical for smooth muscle cell line (MOVAS) phenotypic switching. Cells were treated for 24 hours with glutaminase inhibitors (50mM DON, Sigma-SML0601) in presence or absence of 2mM glutamate suplementation (Gibco-35050061). High-throughput transcriptional profiling revealed that modulation of glutamine and glutamate homeostasis impacted genes involved in protein and extracellular matrix organization, cell motility and microtubule. Thus, we uncovered a novel role for glutamine metabolism in the phenotypic switch in SMCs, a hallmark of vascular remodelling.

Project description:Ciprofloxacin, an inhibitor of bacterial gyrase and topoisomerase IV, was shown to inhibit growth of C. glutamicum with concomitant excretion of L-glutamate. C. glutamicum strains overproducing L-lysine, L-arginine, L-ornithine, and putrescine, respectively, produced L-glutamate instead of the desired amino acid when exposed to ciprofloxacin. Even in the absence of the putative L-glutamate exporter gene yggB, ciprofloxacin effectively triggered L-glutamate production. When C. glutamicum wild type was cultivated under nitrogen-limiting conditions, 2-oxoglutarate rather than L-glutamate was produced as consequence of exposure to ciprofloxacin. Transcriptome analysis revealed that ciprofloxacin increased RNA levels of genes involved in DNA synthesis, repair and modification. Enzyme assays showed that 2-oxoglutarate dehydrogenase activity was decreased due to ciprofloxacin addition. Here, it was shown for the first time that production of L-glutamate by C. glutamicum may be triggered by an inhibitor of DNA synthesis and L-glutamate titers of up to 37 ± 1 mM and a substrate specific L-glutamate yield of 0.13 g/g were reached.

Project description:Profiles of two major acyl-modifications, lysine acetylation and succinylation, under L-glutamate-producting and non-producing conditions in Corynebacterium glutamicum, which is industrially utilized for amino acid fermentation, was analyzed. During glutamate overproduction induced by Tween 40, global lysine acetylation was decreased, while lysine succinylation was increased. A label-free semi-quantitative proteomic analysis identified 591 acetylated proteins with 1,509 unique acetylation sites and 297 succinylated proteins with 790 unique succinylation sites. Lysine acetylation and succinylation targeted most enzymes in the central carbon metabolic pathways that are directly related to glutamate production, including the 2-oxoglutarate dehydrogenase complex (ODHC), a key enzyme for glutamate overproduction.

Project description:The development of mitochondrial medicine is greatly impaired by the lack of knowledge and identification of efficient therapeutic routes targeting mitochondria. To better understand the pathophysiology of MELAS syndrome, neuronal cybrid cells, carrying different mutant loads of the m.3243A>G mutation, were investigated by a metabolomics and transcriptomics combined approach. Specific signatures, identifying MELAS biochemical biomarkers, disclosed the glutamate pathway as a culprit mechanism, establishing a strong correlation between glutamate concentrations and the m.3243A>G heteroplasmy levels. Transcriptomic analyses further revealed peculiar gene clusters, including glutamate, gamma-aminobutyric acid (GABA) and tricarboxylic acid (TCA) cycle pathways. These results were supported by post-mortem brain tissue analysis of a MELAS patient, confirming the dysregulation of the glutamate metabolic pathway. Ketogenic diet known to reduce glutamate toxicity, induced a significant reduction of glutamate level after 48h of ketone body treatment, improved mitochondrial functions alleviating the accumulation of several intermediate metabolites of the TCA cycle in MELAS cells. Thus, the integrated approach using a multi-OMICs strategy on MELAS cybrid cells, disclosed novel insights in the mitochondrial energy failure, identifying glutamate as a potential biomarker of the disease, while highlighting ketogenic diet, a nutrition based strategy, to treat MELAS patients

Project description:Here, we investigated for the first time the systems-wide response of B. subtilis to different simultaneous stresses, i.e. nutrient limitation and high osmolarity. To address the anticipated complexity of the cellular response networks, we combined chemostat experiments under conditions of carbon limitation, salt stress and osmoprotection with multi-omics analyses at the transcriptome, proteome, metabolome and fluxome levels. Our results indicate that the flux through central carbon and energy metabolism is very robust under all conditions studied. The key to achieve this robustness is the adjustment of the biocatalytic machinery to compensate for solvent-induced impairment of enzymatic activities during osmotic stress. The accumulation of the exogenously provided osmoprotectant glycine betaine helps the cell to rescue enzyme activities in the presence of high salt. A major effort of the cell during osmotic stress is the production of the compatible solute proline. This is achieved by the concerted adjustment of multiple reactions around the 2-oxoglutarate node, which drives metabolism towards the proline precursor glutamate. The fine-tuning of the transcriptional and metabolic networks involves functional modules that overarch the individual pathways. We applied transcriptomic, mass spectrometry-based protein, metabolite and 13C-metabolic flux analysis techniques to B. subtilis cells grown under well-controlled conditions in a glucose-limited chemostat at a growth rate of 0.1 h-1 under i) reference conditions, ii) in the presence of 1.2 M NaCl, and iii) in the presence of 1.2 M NaCl and 1 mM GB. Microarray hybridizations were performed with RNA from three biological replicates. The individual samples were labeled with Cy5; a reference pool containing equal amounts of RNA from all 9 samples was labeled with Cy3.