Amniotic fluid metabolomics identifies impairment of glycerophospholipid and amino acid metabolism during congenital Zika syndrome development.

PURPOSE: Our main goal is to identify the alterations in the amniotic fluid (AF) metabolome in Zika virus (ZIKV)-infected patients and their relation to congenital Zika syndrome (CZS) progression. EXPERIMENTAL DESIGN: We applied an untargeted metabolomics strategy to analyze seven AF of pregnant women: healthy women and ZIKV-infected women bearing non-microcephalic and microcephalic fetuses. RESULTS: Infected patients were characterized by glycerophospholipid metabolism impairment, which is accentuated in microcephalic phenotypes. Glycerophospholipid decreased concentration in AF can be a consequence of intracellular transport of lipids to the placental or fetal tissues under development. The increased intracellular concentration of lipids can lead to mitochondrial dysfunction and neurodegeneration caused by lipid droplet accumulation. Furthermore, the dysregulation of amino acid metabolism was a molecular fingerprint of microcephalic phenotypes, specifically serine, and proline metabolisms. Both amino acid deficiencies were related to neurodegenerative disorders, intrauterine growth retardation, and placental abnormalities. CONCLUSIONS AND CLINICAL RELEVANCE: This study enhances our understanding of the development of CZS pathology and sheds light on dysregulated pathways that could be relevant for future studies.

Different Signatures of High Cardiorespiratory Capacity Revealed With Metabolomic Profiling in Elite Athletes.

PURPOSE: High cardiorespiratory capacity is a key determinant of human performance and life expectancy; however, the underlying mechanisms are not fully understood. The objective of this pilot study was to investigate biochemical signatures of endurance-performance athletes using high-resolution nontargeted metabolomics. METHODS: Elite long-distance runners with similar training and anthropometrical records were studied. After athletes' maximal oxygen consumption (V˙O2max) was measured, they were divided into 2 groups: low V˙O2max (<65 mL·kg-1·min-1, n = 7) and high V˙O2max (>75 mL·kg-1·min-1, n = 7). Plasma was collected under basal conditions after 12 hours of fasting and after a maximal exercise test (nonfasted) and analyzed by high-resolution LC-MS. Multivariate and univariate statistics were applied. RESULTS: A total of 167 compounds were putatively identified with an LC-MS-based metabolomics pipeline. Partial least-squares discriminant analysis showed a clear separation between groups. Significant variations in metabolites highlighted group differences in diverse metabolic pathways, including lipids, vitamins, amino acids, purine, histidine, xenobiotics, and others, either under basal condition or after the maximal exercise test. CONCLUSIONS: Taken together, the metabolic alterations revealed in the study affect cellular energy use and availability, oxidative stress management, muscle damage, central nervous system signaling metabolites, nutrients, and compound bioavailability, providing new insights into metabolic alterations associated with exercise and cardiorespiratory fitness levels in trained athletes.

PTM-driven differential peptide display: survey of peptides containing inter/intra-molecular disulfide bridges in frog venoms.

Amphibian defensive skin secretions are complex species-specific mixtures of biologically active molecules, including many uncharacterized peptides. Many of these peptides are post-translationally modified and amongst the modifications discovered so far on amphibian defense peptides, disulfide bonds are quite frequently encountered. The presence of this PTM often complicates the MS-based sequencing. Here we demonstrate a method to target peptides containing inter/intra-molecular S-S bonds applying a PTM-driven differential display. Upon reduction of the disulfide bond both molecular mass and retention time of a peptide are altered. Assembling the LC-MS data by plotting the m/z data against retention time generates a peptide display and overlaying peptide displays of untreated and DTT-reduced material yields a differential display. From such an overlay, peptides originally carrying a disulfide bond are recognized due to the shift in both retention time and m/z values, whereas non cystine containing peptides remain unaltered in the differential display. The success of this approach is demonstrated by the visualization of the cystines-containing peptides in the skin secretion of Odorrana schmackeri, Phyllomedusa burmeisteri, Phyllomedusa rohdei, Kassina senegalensis, and Bombina variegata. The venoms from these different species yield complicated differential displays, showing interesting peptides, allowing one to target them for more detailed structural characterization.