Isotope Labeling Research Articles

Quantitative profiling of PTM stoichiometry by DNA mass tags.

Protein post-translational modification (PTM) serves as an important mechanism for regulating protein function. Accurate assay of PTM stoichiometry, or PTM occupancy, which refers to the proportion of proteins that contain specific modifications, is important for understanding the function of PTMs. We previously developed a novel chemoproteomic strategy "STO-MS" to quantify the PTM stoichiometry in complex biological samples, which employs a resolvable polymer mass tag to differentiate modified proteins and utilizes liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS) techniques to measure PTM stoichiometry. However, the resolution of STO-MS is constrained by the relatively low molecular weight of the mass tag, and the incorporation of isotopic labels not only complicates the sample preparation but also restricts the measurement throughput. To address these challenges, we herein developed "STO-MS+", an enhanced workflow, that incorporates an optimized DNA mass tag and employs a label-free quantitative data analysis approach. We applied STO-MS+ to measure stoichiometry of three distinct PTMs, including endogenous carbonylation induced by arachidonic acid (AA), itaconation, and endogenous O-GlcNAcylation. Our work marks a notable improvement in chemoproteomic methodologies for quantifying post-translational modifications and provides a powerful analytical tool for PTM research.

Vacuum ultraviolet laser dissociation and proteomic analysis of halogenated peptides

Chemical modifications are widely used in research fields such as quantitative proteomics and interaction analyses. Chemical-modification targets can be roughly divided into four categories, including those that integrate isotope labels for quantification purposes, probe the structures of proteins through covalent labeling or cross-linking, incorporate labels to improve the ionization or dissociation of characteristic peptides in complex mixtures, and affinity-enrich various poorly abundant protein translational modifications (PTMs). A chemical modification reaction needs to be simple and efficient for use in proteomics analysis, and should be performed without any complicated process for preparing the labeling reagent. High reaction specificity, which reduces product complexity, and mild biocompatible reaction conditions are also favored. In addition, modification labels should be compatible with mass spectrometry to prevent interference from ionization and dissociation processes. Pulsed ultraviolet (UV) lasers can produce large amounts of active radical species within a few nanoseconds for use in rapid photochemical-modification processes. Usually, UV lasers with wavelengths greater than 240 nm are used in current in-situ photochemical-modification methods; consequently, special conjugated photoreaction probes need to be designed and oxidants and catalysts added, which reduce the biocompatibility of the reaction. The high single-photon energy of the 193 nm laser is capable of efficiently exciting conventional photo-inert substances in aqueous solution, leading to efficient photochemical peptide modifications. In this study, we developed a new method for photochemically brominating and iodinating enzymatic protein samples extracted from complex tissue with a 193 nm ArF nanosecond pulsed laser, which efficiently brominated tyrosine, histidine, and tryptophan, and iodinated tyrosine and histidine. Tandem mass spectrometry (MS/MS) can generate fragmentation patterns of ions which can afford diagnostic molecular fingerprints to decipher sequences of biopolymers such as peptides. Peptide fragmentation is commonly implemented using collision-based, electron-based, or photodissociation-based methods. Compared with the most commonly used collision-based methods, ultraviolet photodissociation (UVPD) uses high-energy ultraviolet photons with wavelengths shorter than 200 nm to excite and dissociate ions. Single-pulse excitation can provide the energy required to promote ions into their excited electronic states, with excitation speeds of up to several nanoseconds. Since dissociation may occur directly from the excited states, UVPD spectra can show a wide variety of fragmentation pathways, thereby providing more sequence and structural information. The most commonly used wavelengths are 157, 193, and 266 nm. UVPD has been integrated into high-resolution orbitrap mass spectrometer by adding optical windows and other optics to direct the photons to the analyte ions, and by implementing a triggering method that synchronizes the photoirradiation process with ion-analysis events. The large photoabsorption cross sections of peptides at 193 nm and the resulting high internal energy deposition can generate abundant fragment ions and achieve high sequence coverage. The excellent fragmentation performance offered by 193 nm UVPD of peptides with its high sequence coverage and lack of charge-state dependence, has motivated its use in high-throughput proteomics. Photochemically brominated and iodinated mouse-liver tryptic peptides were further characterized by 193 nm UVPD tandem mass spectrometry with the aim of analyzing their sequences, modification sites, and photodissociation mechanisms. Br and I atoms strongly absorb 193 nm photons; consequently, UVPD can cleave C-Br/C-I bonds at halogenated sites to generate peptide radical ions, with further peptide-backbone fragmentation caused by radical migration. In addition, the combination of 193 nm UVPD with conventional high-energy collision-induced dissociation (HCD) mode improves the identification-reliability of halogenation sites in proteomics. Therefore, integrating photochemical halogenation and 193 nm UVPD can trigger novel radical-dissociation pathways, thereby improving analytical proteomics performance.

Enhanced nano-LC-MS for analyzing dansylated oral cancer tissue metabolome dissolved in solvents with high elution strength.

Tissue metabolomics analysis, alongside genomics and proteomics, offers crucial insights into the regulatory mechanisms of tumorigenesis. To enhance metabolite detection sensitivity, chemical isotope labeling (CIL) techniques, such as dansylation, have been developed to improve metabolite separation and ionization in mass spectrometry (MS). However, the dissolution of hydrophobic derivatized metabolites in solvents with high acetonitrile content limits the use of liquid chromatography (LC) systems with small-volume reversed-phase (RP) columns. In this study, we established a nano-LC-MS system with an online dilution design to address this issue, enabling sensitive analysis of oral cancer tissue metabolomes. Our nano-LC system features a flow path design with online sample dilution before an RP trap column and backflushing of the trap column before entering the analytical column. Compared to other nano-LC systems, both with and without online dilution designs, our system demonstrates the superiority of the T-connector-based dilution method. Using only 1/20th of the sample required for popular micro-LC systems, our nano-LC detects a larger number of peak pairs with similar recovery rates for both hydrophilic and hydrophobic metabolites, ensuring unbiased results. Thirty-two matched pairs of oral squamous cell carcinoma (OSCC) tissue samples and adjacent noncancerous tissues (ANTs) underwent high-throughput CIL-metabolome analysis using our nano-LC system. Compared to our previous micro-LC methods, the nano-LC-MS system exhibits enhanced detection sensitivity, significantly reducing sample requirements. Our findings highlight the efficacy of our platform for metabolomic analysis with limited sample amounts. The nano-LC system's ability to analyze samples dissolved in strong eluents suggests potential applications for handling other hydrophobic compounds using RPLC or other separation methods facing similar solvent incompatibility issues. This approach holds promise for identifying novel metabolite biomarkers for oral cancers, advancing our understanding of tumorigenesis, and enhancing clinical applications.

Photochemistry of Microsolvated Nitrous Acid: Observation of the Water-Separated Complex of Nitric Oxide and Hydroxyl Radical.

The photochemistry of nitrous acid (HONO) plays a crucial role in atmospheric chemistry as it serves as a key source of hydroxyl radicals (OH) in the atmosphere; however, our comprehension of the underlying mechanism for the photochemistry of HONO especially in the presence of water is far from being complete as the transient intermediates in the photoreactions have not been observed. Herein, we report the photochemistry of microsolvated HONO by water in a cryogenic N2 matrix. Specifically, the 1:1 hydrogen-bonded water complex of HONO was facially prepared in the matrix through stepwise photolytic O2 oxidation of the water complex of imidogen (NH-H2O) via the intermediacy of the elusive water complex of peroxyl isomer HNOO. Upon photolysis at 193 nm, the matrix-isolated HONO-H2O complex decomposes by yielding the ternary water complex of OH and NO due to the matrix cage effect. The identification of this rare water-separated radical pair (OH-H2O-NO) with matrix-isolation infrared and ultraviolet-visible spectroscopy is aided by D, 15N, and 18O isotope labeling and quantum chemical calculations at the (U)CCSD/AVTZ level of theory, and its most stable structure exhibits separate hydrogen bonding interactions of the OH and NO radicals with H2O via OH···OH2 and ON···HOH contacts, respectively. This ternary complex is extremely unstable, as it undergoes spontaneous radical recombination to reform the HONO-H2O complex in the temperature range of 4-12 K through quantum-mechanical tunneling with 16/18O, H/D, 14/15N kinetic isotopic effects of 1.43, 2.33, and 0.91, respectively. At increased temperatures from 15 to 21 K, the recombination proceeds predominantly by overcoming the activation barrier with an estimated height of 0.12(1) kcal/mol.

Tissue-specific responses of the central carbon metabolism in tomato fruit to low oxygen stress.

Tomato (Solanum lycopersicum L.) is an important model plant whose fleshy fruit consists of well-differentiated tissues. Recently it was shown that these tissues develop hypoxia during fruit development and ripening. Therefore, we employed a combination of metabolomics and isotopic labeling to investigate the central carbon metabolic response of tomato fruit tissues (columella, septa and mesocarp) to low O2 stress. The concentration and 13C-label enrichment of intermediates from the central carbon metabolism were analyzed using gas chromatography-mass spectrometry. The results showed an increase in glycolytic activity and the initiation of fermentation in response to low O2 conditions. In addition, the up-regulation of the GABA shunt and accumulation of amino acids, alanine and glycine, were observed under low O2 conditions. Notably, tissue specificity was observed at the metabolite level, with concentrations of most metabolites being highest in columella tissue. In addition, there were tissue-specific differences in the central carbon metabolism with the columella exhibiting the highest metabolic activity and sensitivity to the changes in O2 concentration, followed by septa and mesocarp tissues. Our results are consistent with common plant responses and adaptive mechanisms to low O2 stress, while unravelling some tissue-specific differences, increasing our understanding of the intact fruit response to low O2 stress.

The History of Studies on Oxetane Ring Formation in Paclitaxel Biosynthesis.

There is no doubt that breakthroughs in the enzyme-mediated formation of the oxetane ring in paclitaxel biosynthesis constitute significant milestones in the biosynthesis of complex natural products. In this review, we summarize the understanding of the biosynthesis of the oxetane ring of paclitaxel from different viewpoints. Generally, it covers five aspects, (1) a different understanding of the mechanistic formation of the oxetane ring on the basis of sound chemical reasoning, (2) a reasonable speculation of the biosynthetic pathways and suitable surrogate substrates for oxetane ring formation based on the natural and chemical logical analysis, (3)Taxus genome-enabled enzymes identification, (4) the discovery of different enzymes that mediate oxetane ring formation, and (5) a mechanistic investigation involving the use of isotopic labelling experiments and quantum chemical calculations. This review provides a detailed overview of the history of the studies on the oxetane ring formation in paclitaxel biosynthesis, which may be useful for a better understanding this process in combined view of nature, chemistry and biology logics, also for efficient heterologous reconstruction of the paclitaxel biosynthetic pathway in the future.

Acid-Promoted Phosphorylation of Ynones for the Synthesis of Phosphoryl Enones.

An efficient phospha-aldol/Meyer-Schuster rearrangement cascade reaction between propargylic aldehydes and phosphine oxides has been developed in which various phosphoryl enones were obtained in moderate to excellent yields. A comprehensive series of mechanistic experiments, including the identification of key intermediates and the application of 18O isotope labeling, has confirmed that this cascade reaction proceeds through a phospha-aldol followed by Meyer-Schuster rearrangement cascade reaction.

Tracing of Amino Acids Dynamics in Cell Lines Based on 18O Stable Isotope Labeling.

Metabolite levels and turnover rates are necessary to understand metabolomic dynamics in a living organism fully. Amino acids can play distinct roles in various cellular processes, and their abnormal levels are associated with pathological conditions, including cancer. Therefore, their levels, especially turnover rates, may provide enormous information about a phenotype. 13C- or 13C,15N-labeled amino acids have also been commonly used to trace amino acid metabolism. This study presented a new methodology based on 18O labeling for amino acids that relied on monitoring mass isotopologues to calculate the turnover rates of amino acids. The method optimization studies were carried over for selective amino acid monitoring. This methodology provides a rapid, robust, and simple GC-MS method for analyzing the fluxes of amino acid metabolism. The developed method was applied to fetal human colon (FHC) and human colon carcinoma (Caco-2) cell lines to determine cancer-induced shifts in the turnover rates of amino acids. These results defined metabolic reprogramming in Caco-2 cells through increased glutamate and serine turnovers and sharply decreased turnovers of aspartate, threonine, and methionine, therefore pointing to some metabolic vulnerabilities in the metabolism of cancerous cells. The simple mechanism of the developed methodology, the availability of affordable 18O-enriched water, and the ease of application can open a new arena in fluxomics analysis.

Unveiling Heavier Dihydropyridine Chalcogenol Esters in Metallaphotoredox Catalyst-Enabled Regioselective Hydrothio(seleno)carbonylation.

Herein, aromaticity-driven thio(seleno)ester group transfer from novel 1,4-dihydropyridine thio(seleno)esters to alkene feedstocks is disclosed by merging palladium and photoredox catalysis. In this process, photoactivation of dihydropyridine thio(seleno)esters is integrated with regioselective hydrometalation of alkenes, avoiding photoinduced Pd-C bond homolysis of organopalladium intermediates. Additionally, a regioselective hydroselenocarbonylation of an alkene is accomplished for the first time using a bench-stable selenoester reagent. The activation mode of novel dihydropyridine thioesters has been illustrated by detailed mechanistic studies, spectroscopic analysis, intermediate trapping, and isotope labeling experiments.

A Unique Intramolecular Redox Reaction by Unidirectional Migration of Three Hydrogen Atoms: Theoretical Elucidation of the 3H-Transfer Sequence.

The intramolecular migration of three hydrogen atoms from one moiety of a gaseous radical cation to the other prior to fragmentation is an extremely rare type of redox reaction. Within the scope of this investigation, this scenario requires an ionized but electron-rich arene acceptor bearing a para-(3-hydroxyalkyl) residue. The precise mechanism of such unidirectional 3H transfer processes, including the order of the individual H transfer steps, has remained unclear in spite of previous isotope labelling and recent infrared ion spectroscopy (IRIS) studies. Herein, the details of this peculiar process have been investigated for ionized 4-(N,N-dimethylaminophenyl)-2-butanol, 2, by state-of-the-art density functional theory (DFT) calculations. The energetically most favorable pathway consists of a sequence of successive 1,4-, 1,6- and 1,5-H steps. During these steps the secondary alcohol functionality is oxidized to a carbonyl group and the radical-cationic aniline ring is reduced to an ionized 2,3-dihydroaniline unit. Several alternative sequences, such as three successive 1,5-H shifts, could be excluded. A concomitant unidirectional 2H migration reaction of the ion 2 was also investigated and the intermediacy of ion-neutral complexes (INCs) enabling sequential hydride and proton transfer was confirmed by the calculations.

Tandem Catalysis for Plastic Depolymerization: In Situ Hydrogen Generation via Methanol APR for Sustainable PE Hydrogenolysis.

Depolymerizing plastic waste through hydrogen-based processes, such as hydrogenolysis and hydrocracking, presents a promising solution for converting plastics into liquid fuels. However, conventional hydrogen production methods rely heavily on fossil fuels, exacerbating global warming. This study introduces a novel approach to plastic waste hydrogenolysis that utilizes in situ hydrogen generated via the aqueous phase reforming (APR) of methanol, a biomass-derived chemical offering a more sustainable alternative. Our results show that a bimetallic Ru-Pt/TiO2 catalyst achieved high conversion (85.1%) and selectivity (81.0%) towards liquid fuels and lubricant oils in a tandem process combining polyethylene (PE) hydrogenolysis and methanol APR. By tuning the metal loading, we identified that Pt enhances hydrogen production through methanol APR, while Ru drives C-C bond cleavage, which is crucial for PE hydrogenolysis. Isotope labeling analysis confirmed that hydrogen generated from methanol APR is effectively utilized in the PE hydrogenolysis reaction. This method was also successfully applied to post-consumer polyolefin waste, with selectivity toward valuable products ranging from 75.0% to 88.9%. This study highlights an innovative strategy to reduce reliance on fossil-fuel-derived hydrogen in plastic waste depolymerization, promoting both sustainability and environmental protection.

SQSTM1/P62 Mediates the Effects of CPNE3 on the Epithelialmesenchymal Transition and Migratory Inhibition of Lung Adenocarcinoma Cells.

Copine-3 (CPNE3) is a conservative calcium-dependent phospholipid-binding protein belonging to the copines protein family. CPNE3 has been implicated in the development and progression of several diseases, including cancer. Herein, we investigated the molecular mechanisms through which CPNE3 regulates the migration of lung adenocarcinoma (LUAD) cells in vitro. Western blotting and immunohistochemical assays showed that CPNE3 is widely distributed in LUAD tissues and cell lines and that CPNE3 downregulation promotes the migration of human LUAD A549 cells. Stable isotope labelling with amino acids in cell culture, which is a quantitative proteomics approach coupled with bioinformatic analyses, revealed that CPNE3 regulates SQSTM1/p62 and vimentin expression, indicating that CPNE3 may mediate epithelial-mesenchymal transition (EMT). CPNE3 silencing by siRNA upregulated vimentin levels but downregulated E-cadherin levels in the A549 cells. Furthermore, SQSTM1/p62 knockdown enhanced migratory ability and EMT progression in CPNE3-silenced A549 cells. Overall, CPNE3 knockdown was found to promote EMT by inhibiting SQSTM1/p62 signalling and facilitating cell migration. Our findings highlight the role of CPNE3 as a tumour suppressor, providing deeper insights into its carcinogenic roles in LUAD.

Nitrogen Electrochemical Reduction Reaction Pathways Evidenced by Online Electrochemical Mass Spectrometry and Isotope Labeling on the MoS2 Surface

Nitrogen Electrochemical Reduction Reaction Pathways Evidenced by Online Electrochemical Mass Spectrometry and Isotope Labeling on the MoS₂ Surface

Efficient adsorption and detection of steroid hormones in foods through the combination of novel magnetic TAPB-COF materials with click isotope probes.

Matrix effects pose a significant challenge in food analysis for the quantitative analysis of complex food samples. Herein, a novel magnetic covalent organic framework nanocomposite and the copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) click reaction-based stable isotope labeling (SIL) method were presented for highly selective and sensitive detection of steroid hormones in food samples using HPLC-MS/MS. The nanocomposite, Fe3O4@TAPB-COF, with acore-shell structure exhibited high adsorption capacities for steroid hormones. Combined with a SIL method based on the CuAAC click reaction, steroid hormones were accurately quantified in food samples with high sensitivity and selectivity. A pair of SIL agents, N-(2-azidoethyl)aniline (d0-NAEA) and d5-N-(2-azidoethyl)aniline (d5-NAEA), was synthesized to label steroid hormones in the samples and standard solutions, respectively. The labeling reaction is highly specific, and the formation of the derivatives is easily ionized by MS, thus overcoming matrix effects. More surprisingly, the ionization efficiency of steroid hormones increased by a factor of 4 to 56, with matrix effects ranging from 87.3 to 99.3%. Under optimal conditions, this method exhibited a low limit of detection (LOD) ranging from 0.1 to 2.6 μg L-1 and overcame the interference of matrix effects for trace-level steroid hormone analysis in foodstuffs.

Target Discovery Driven by Chemical Biology and Computational Biology.

Target identification is crucial for drug screening and development because it can reveal the mechanism of drug action and ensure the reliability and accuracy of the results. Chemical biology, an interdisciplinary field combining chemistry and biology, can assist in this process by studying the interactions between active molecular compounds and proteins and their physiological effects. It can also help predict potential drug targets or candidates, develop new biomarker assays and diagnostic reagents, and evaluate the selectivity and range of active compounds to reduce the risk of off-target effects. Chemical biology can achieve these goals using techniques such as changing protein thermal stability, enzyme sensitivity, and molecular structure and applying probes, isotope labeling and mass spectrometry. Concurrently, computational biology employs a diverse array of computational models to predict drug targets. This approach also offers innovative avenues for repurposing existing drugs. In this paper, we review the reported chemical biology and computational biology techniques for identifying different types of targets that can provide valuable insights for drug target discovery.

N-terminomics profiling of host proteins targeted by excretory-secretory proteases of the nematode Angiostrongylus vasorum identifies points of interaction with canine coagulation and complement cascade.

The cardiopulmonary nematode Angiostrongylus vasorum can cause severe disease in dogs, including coagulopathies manifesting with bleeding. We analysed A. vasorum excretory/secretory protein (ESP)-treated dog plasma and serum by N-terminome analysis using Terminal Amine Isotopic Labelling of Substrates (TAILS) to identify cleaved host substrates. In plasma and serum samples 430 and 475 dog proteins were identified, respectively. A total of eight dog proteins were significantly cleaved at higher levels upon exposure to A. vasorum ESP: of these, three were coagulation factors (factor II, V and IX) and three were complement proteins (complement C3, C4-A and C5). Comparison with human motif sequence orthologues revealed known cleavage sites in coagulation factor IX and II (prothrombin). These and further identified cleavage sites suggest direct or indirect activation or proteolysis of complement and coagulation components through A. vasorum ESP, which contains several proteases. Further studies are needed to validate their substrate specificity.

Distinct Fermi Resonance Patterns of Weak Coupling in 2D-IR Spectra of 5-Cyanoindole Revealed by Isotope Labeling.

Fermi resonance is a common phenomenon, and a hidden caveat exists in the applications of infrared probes, causing spectral complication and shorter vibrational lifetime. In this work, using the cyanotryptophan (CNTrp) side chain model compound 5-cyanoindole (CN-5CNI), we performed Fourier transform infrared spectroscopy (FTIR) and two-dimensional infrared (2D-IR) spectroscopy on unlabeled 12C14N-5CNI and its isotopically labeled substituents (12C15N-5CNI, 13C14N-5CNI, 13C15N-5CNI) and demonstrated the existence of Fermi resonance in 5CNI. By constructing the Hamiltonian and simulating 2D-IR spectra, we show that the distinct Fermi resonance 2D-IR patterns in various isotope substituents are determined by the quantum mixing consequences at the v = 1 state, as well as the v = 2 state, where the Fermi coupling and anharmonicity play a crucial role. Our work provides important insights into the elusive type of Fermi resonance, where the coupling is much smaller than the anharmonicity, which is termed the weak coupling case.

Catalyst-Free Nitrogen Fixation by Microdroplets through a Radical-Mediated Disproportionation Mechanism under Ambient Conditions.

Nitrogen fixation is essential for the sustainable development of both human society and the environment. Due to the chemical inertness of the N≡N bond, the traditional Haber-Bosch process operates under extreme conditions, making nitrogen fixation under ambient conditions highly desirable but challenging. In this study, we present an ultrasonic atomizing microdroplet method that achieves nitrogen fixation using water and air under ambient conditions in a rationally designed sealed device, without the need for any catalyst. The total nitrogen fixation rate achieved is 6.99 μmol/h, yielding ammonium as the reduction product and nitrite and nitrate as the oxidation products, with hydrogen peroxide produced as a byproduct at a rate of 4.29 μmol/h. Using electron paramagnetic resonance (EPR) spectroscopy, we captured reactive species, including hydrogen, hydroxyl, singlet oxygen, superoxide anion, and NO radicals. In conjunction with in situ mass spectrometry (MS) and isotope labeling, we confirmed the presence of nitrogen-containing intermediates, such as HN═NOH+•, H2N-N(OH)2+•, HNO+, and NH2OH+•. Supported by these findings and theoretical calculations, we propose a radical-mediated nitrogen disproportionation mechanism. Simulations of naturally occurring condensed microdroplets also demonstrated nitrogen redox fixation. This microdroplet-based method not only offers a potential pathway for nitrogen fixation in practical applications and sustainable development but also deepens our understanding of the natural nitrogen cycle.

Failure to repair damaged NAD(P)H blocks de novo serine synthesis in human cells

BackgroundMetabolism is error prone. For instance, the reduced forms of the central metabolic cofactors nicotinamide adenine dinucleotide (NADH) and nicotinamide adenine dinucleotide phosphate (NADPH), can be converted into redox-inactive products, NADHX and NADPHX, through enzymatically catalyzed or spontaneous hydration. The metabolite repair enzymes NAXD and NAXE convert these damaged compounds back to the functional NAD(P)H cofactors. Pathogenic loss-of-function variants in NAXE and NAXD lead to development of the neurometabolic disorders progressive, early-onset encephalopathy with brain edema and/or leukoencephalopathy (PEBEL)1 and PEBEL2, respectively.MethodsTo gain insights into the molecular disease mechanisms, we investigated the metabolic impact of NAXD deficiency in human cell models. Control and NAXD-deficient cells were cultivated under different conditions, followed by cell viability and mitochondrial function assays as well as metabolomic analyses without or with stable isotope labeling. Enzymatic assays with purified recombinant proteins were performed to confirm molecular mechanisms suggested by the cell culture experiments.ResultsHAP1 NAXD knockout (NAXDko) cells showed growth impairment specifically in a basal medium containing galactose instead of glucose. Surprisingly, the galactose-grown NAXDko cells displayed only subtle signs of mitochondrial impairment, whereas metabolomic analyses revealed a strong inhibition of the cytosolic, de novo serine synthesis pathway in those cells as well as in NAXD patient-derived fibroblasts. We identified inhibition of 3-phosphoglycerate dehydrogenase as the root cause for this metabolic perturbation. The NAD precursor nicotinamide riboside (NR) and inosine exerted beneficial effects on HAP1 cell viability under galactose stress, with more pronounced effects in NAXDko cells. Metabolomic profiling in supplemented cells indicated that NR and inosine act via different mechanisms that at least partially involve the serine synthesis pathway.ConclusionsTaken together, our study identifies a metabolic vulnerability in NAXD-deficient cells that can be targeted by small molecules such as NR or inosine, opening perspectives in the search for mechanism-based therapeutic interventions in PEBEL disorders.Graphical

Stable isotope labelling to elucidate ring cleavage mechanisms of disinfection by-product formation during chlorination of phenols

Stable isotope labelling to elucidate ring cleavage mechanisms of disinfection by-product formation during chlorination of phenols