Effects of Pregnancy on Plasma Sphingolipids Using a Metabolomic and Quantitative Analysis Approach.

Changes in the maternal metabolome, and specifically the maternal lipidome, that occur during pregnancy are relatively unknown. The objective of this investigation was to evaluate the effects of pregnancy on sphingolipid levels using metabolomics analysis followed by confirmational, targeted quantitative analysis. We focused on three subclasses of sphingolipids: ceramides, sphingomyelins, and sphingosines. Forty-seven pregnant women aged 18 to 50 years old participated in this study. Blood samples were collected on two study days for metabolomics analysis. The pregnancy samples were collected between 25 and 28 weeks of gestation and the postpartum study day samples were collected ≥3 months postpartum. Each participant served as their own control. These samples were analyzed using a Ultra-performance liquid chromatography/mass spectroscopy/mass spectroscopy (UPLC/MS/MS) assay that yielded semi-quantitative peak area values that were used to compare sphingolipid levels between pregnancy and postpartum. Following this lipidomic analysis, quantitative LC/MS/MS targeted/confirmatory analysis was performed on the same study samples. In the metabolomic analysis, 43 sphingolipid metabolites were identified and their levels were assessed using relative peak area values. These profiled sphingolipids fell into three categories: ceramides, sphingomyelins, and sphingosines. Of the 43 analytes measured, 35 were significantly different during pregnancy (p < 0.05) (including seven ceramides, 26 sphingomyelins, and two sphingosines) and 32 were significantly higher during pregnancy compared to postpartum. Following metabolomics, a separate quantitative analysis was performed and yielded quantified concentration values for 23 different sphingolipids, four of which were also detected in the metabolomics study. Quantitative analysis supported the metabolomics results with 17 of the 23 analytes measured found to be significantly different during pregnancy including 11 ceramides, four sphingomyelins, and two sphingosines. Fourteen of these were significantly higher during pregnancy. Our data suggest an overall increase in plasma sphingolipid concentrations with possible implications in endothelial function, gestational diabetes mellitus (GDM), intrahepatic cholestasis of pregnancy, and fetal development. This study provides evidence for alterations in maternal sphingolipid metabolism during pregnancy.

Natural Algaecide Sphingosines Identified in Hybrid Straw Decomposition Driven by White-Rot Fungi.

Harmful algal blooms (HABs), which are promoted by eutrophication and intensified by global warming, occur worldwide. Allelochemicals, which are natural chemicals derived from plants or microbes, are emerging weapons to eliminate these blooms. However, the cost and technical challenges have limited the discovery of novel antialgal allelochemicals. Herein, the decomposition of agricultural straws is manipulated by white-rot fungi and achieved elevated antialgal efficiency. The transcriptomic analysis reveals that nutrient limitation activated fungal decomposition. By using a comparative nontarget metabolomics approach, a new type of allelochemical sphingosines (including sphinganine, phytosphingosine, sphingosine, and N-acetylsphingosine) is identified. These novel natural algaecides exhibit superior antialgal capability, with as high as an order of magnitude lower effective concentration on blooming species than other prevalent allelochemicals. The co-expression relationship between transcriptomic and metabolomic results indicate that sphinganine is strongly correlated with the differentially expressed lignocellulose degradation unigenes. The algal growth suppression is triggered by the activation of programmed cell death, malfunction of algal photosystem and antioxidant system, the disruption on CO2 assimilation and light absorption. The sphingosines reported here are a new category of allelochemicals in addition to the well-known antialgal natural chemicals, which are potential species-specific agents for HABs control identified by multi-omics methodology.

Chirality-Puckering correlation and intermolecular interactions in Sphingosines: Rotational spectroscopy of jaspine B3 and its monohydrate.

Chirality is determinant for sphingosine biofunctions and pharmacological activity, yet the reasons for the biological chiral selection are not well understood. Here, we characterized the intra- and intermolecular interactions at the headgroup of the cytotoxic anhydrophytosphingosine jaspine B, revealing chirality-dependent correlations between the puckering of the ring core and the formation of amino-alcohol hydrogen bond networks, both in the monomer and the monohydrate. Following the specific synthesis of a shortened 3-carbon side-chain molecule, denoted jaspine B3, six different isomers were observed in a jet expansion using broadband (chirped-pulsed) rotational spectroscopy. Additionally, a single isomer of the jaspine B3 monohydrate was observed, revealing the insertion of water in between the hydroxy and amino groups and the formation of a network of O-H···N-H···Oring hydrogen bonds. The specific jaspine B3 stereochemistry thus creates a double-faced molecule where the exposed lone-pair electrons may easily catalyze the formation of intermolecular aggregates and determine the sphingosine biological properties.

Metabolomic and lipidomic characterization of an X-chromosome deletion disorder in neural progenitor cells by UHPLC-HRMS.

INTRODUCTION: Intellectual disorders involving deletions of the X chromosome present a difficult task in the determination of a connection between symptoms and metabolites that could lead to treatment options. One specific disorder of X-chromosomal deletion, Fragile X syndrome, is the most frequently occurring of intellectual disabilities. Previous metabolomic studies have been limited to mouse models that may not have sufficiently revealed the full biochemical diversity of the disease in humans. OBJECTIVES: The primary objective of this study was to elucidate the human biochemistry in X-chromosomal deletion disorders through metabolomic and lipidomic profiling, using cells from a X-deletion patient as a representative case. METHODS: Metabolomic and lipidomic analysis was performed by UHPLC-HRMS on neural progenitor (NP) cells isolated from an afflicted female patient versus normal neural progenitor cells. RESULTS: Results showed perturbations in several metabolic pathways, including those of arginine and proline, that significantly impact both neurotransmitter generation and overall brain function. Coincidently, dysregulation was observed for lipids involved in both cellular structure and membrane integrity. The trends of observed metabolomic changes, as well as lipidomic profiling from identified features, are discussed. CONCLUSION: The lipidomic and metabolomic profiles of NP cell samples exhibited significant differentiation associated with partial deletion of the X chromosome. These findings suggest that rare X-chromosomal deletion disorders are not only a mental disorder limited to alterations in local neuronal functions, but are also metabolic diseases.

In search of constrained FTY720 and phytosphingosine analogs as dual acting anticancer agents targeting metabolic and epigenetic pathways.

A series of compounds containing pyrrolidine and pyrrolizidine cores with appended hydrophobic substituents were prepared as constrained analogs of FTY720 and phytosphingosine. The effect of these compounds on the viability of cancer cells, on downregulation of the nutrient transport systems, and on their ability to cause vacuolation was studied. An attempt to inhibit HDACs with some phosphate esters of our analogs was thwarted by our failure to reproduce the reported inhibitory action of FTY720-phosphate.

Barcode e bioprospecção de metabólitos das algas marinhas Laurencia aldingensis, L. dendroidea e Laurenciella sp. (Ceramiales, Rhodophyta) / Barcode and bioprospecting of metabolites from the marine algae Laurencia aldingensis, L. dendroidea e Laurenciella sp. (Ceramiales, Rhodophyta)

A natureza e diversidade das estruturas químicas com atividade farmacológica que se tem encontrado nos organismos marinhos justificam a busca por novos compostos que são de interesse nas mais diversas áreas de aplicação. As espécies de macroalgas vermelhas, em especial Laurencia spp., merecem destaque pela enorme variedade de terpenos e acetogeninas que produzem, sendo consideradas de grande potencial na produção de novos fármacos. O estudo de seus constituintes pode fornecer importantes subsídios para a quimiotaxonomia, ecologia química, caracterização das espécies e avaliação do potencial biotecnológico. Baseado nisso, Laurencia aldingensis, L. dendroidea e Laurenciella sp. foram selecionadas para o presente estudo para isolamento, caracterização e teste de atividades biológicas dos seus compostos. A técnica do DNA barcoding foi utilizada como ferramenta de diagnóstico para garantir a similaridade entre as amostras de cada espécie, que foram coletadas em época e locais diferentes. Do extrato orgânico de Laurencia aldingensis, nove substâncias foram isoladas, sendo quatro esfingosinas (1-4), três terpenos (5-7) e duas novas substâncias halogenadas (8 e 9). Do extrato orgânico de Laurencia dendroidea formam isolados dois terpenos halogenados conhecidos (10, 11) e, do extrato de Laurenciella sp. três novas substâncias halogenadas alifáticas insaturadas (12-14), assim como um ácido graxo (15) e um esterol (16) conhecidos. Dentre elas, a 8 apresentou atividade citotóxica, mas não se mostrou seletivo, e as substâncias 4 e 11 apresentaram atividade esquistossomicida, bastante promissora. No entanto, nenhum deles apresentou atividade antioxidante. Diante desta investigação, podemos dizer que as informações geradas com os estudos de Laurencia aldingensis, L. dendroidea e Laurenciella sp. expandiram significantemente o conhecimento no que tange a diversidade química no gênero e o potencial biológico-farmacêutico dos mesmos

The nature and diversity of chemical structures with pharmacological activity that have been found in marine organisms justifies the search for new compounds that may have applications in various areas of interest. Species of red seaweeds, especially Laurencia spp., are special because of the unprecedented variety of terpenes and acetogenins they produce that are considered potentially useful for the production of new drugs. Study of their constituents can also provide important insights relating to their chemotaxonomy, chemical ecology, characterization of species and biotechnological potential. On this basis Laurencia aldingensis, L. dendroidea and Laurenciella sp., were selected for study and isolation, characterization, and biological activity assessment of isolatable quantities of their compounds. The technique of DNA barcoding was used as a diagnostic tool to ensure similarity between samples of each species collected at different times and places. From the organic extract of Laurencia aldingensis nine compounds were isolated; four sphingosines (1-4), three terpenes (5-7) and other two new halogenated compound (8, 9). From the organic extract of Laurencia dendroidea two known halogenated terpenes (10, 11) were isolated while from a similar extract of Laurenciella sp., three new halogenated aliphatic compounds (12-14) were isolated together with known fatty acid (15) and sterol (16). Among all isolates, 8 demonstrated unspecific cytotoxic activity and compounds 4 and 11 showed promising schistosomicidal activity. In applied antioxidant assays none of the isolates we noted to have activity. From the overall investigation it is also clear that the information gleaned from the studies of Laurencia aldingensis, L. dendroidea and Laurenciella sp., significantly expanded our knowledge base concerning chemical diversity in the genus Laurencia and their biological-pharmaceutical potential

Sphingosines Derived from Marine Sponge as Potential Multi-Target Drug Related to Disorders in Cancer Development.

Haliclona tubifera, marine sponge species abundant in Brazilian coastline, presents only a few papers published in the literature. Recently, we have reported the isolation of two modified C18 sphingoid bases: (2R,3R,6R,7Z)-2-aminooctadec-7-ene-1,3, 6-triol and and (2R,3R,6R)-2-aminooctadec-1,3,6-triol. In order to continue our research, in this work aimed at the biological investigation of fractions that led to the isolation of these compounds. We evaluated the cytotoxic effect of marine sponge H. tubifera fractions in glioma (U87) and neuroblastoma (SH-SY5Y) human cell lines. In addition, considering the link between cancer, imbalance of reactive oxygen species and coagulation disorders, we also investigated the in vitro effects on blood coagulation and their redox properties. We showed that the ethyl acetate (EtOAc) fraction, rich in sphingoid bases, had important cytotoxic effects in both cancer cell lines with an IC50 < 15 µg/mL and also can inhibit the production of peroxyl radicals. Interestingly, this fraction increased the recalcification time of human blood, showing anticoagulant properties. The present study indicates the sphingosines fraction as a promising source of chemical prototypes, especially multifunctional drugs in cancer therapy.