Orange juice intake by obese and insulin-resistant subjects lowers specific plasma triglycerides: A randomized clinical trial.

BACKGROUND & AIMS: Dyslipidaemia is usually common in obesity, insulin resistance, and type 2 diabetes mellitus. Clinical trials suggest that orange juice may have a positive impact on lipid metabolism and blood lipid profiles; however conflicting results have been reported. Here, we applied a combined untargeted/targeted lipidomic analysis of plasma to examine the impact of orange (Citrus sinensis) juice intake on the lipidome profile of obese and insulin-resistant subjects. METHODS: Twenty-five participants, both sexes, aged 40-60 years, with obesity and insulin resistance (homeostasis model assessment of insulin resistance (HOMA-IR) index >2.71) ingested 400 mL of orange juice 'Pera' (C. sinensis) for 15 d. Cardiometabolic biomarkers, anthropometric parameters, blood pressure, and plasma lipidomic analysis results were assessed at the beginning and end of the intervention. RESULTS: After the 15-d intervention, a significant decrease was observed in the diastolic blood pressure and blood lipid profile. Among plasma lipidomes, 316 lipid molecules were identified, with the triglycerides (TGs) subclass being the most abundant (n = 106). Plasma lipidome profiling revealed a major signature of the intervention; with concentrations of 37 TG species decreasing after intervention. Qualitatively, oleic and linoleic acids were among the most prevalent fatty acids linked to the altered TG species, representing 50% of TG chains. Modulated TG species were positively correlated with total TG and very low-density lipoprotein levels, as well as systolic and diastolic blood pressure. A strong inter-individual trend was observed, wherein, compared with less responsive subjects, the high responsive subjects displayed the highest decrease in the concentrations of altered TG species, as as well as systolic blood pressure (decrease of 10.3 ± 6.8 mmHg) and body weight (decrease of 0.67 ± 0.71 kg). CONCLUSIONS: These findings suggest that orange juice has a positive impact on lipid metabolism, mainly regarding the composition of TG-specific fatty acid chains and cholesterol esters, protecting against insulin resistance. Furthermore, lipidomics may help clarify alterations at the molecular level after an intervention, contributing to improve the evaluation of the link between dyslipidaemia, insulin resistance, and nutrition.

Orange juice intake by obese and insulin-resistant subjects lowers specific plasma triglycerides: a randomized clinical trial

BACKGROUND & AIMS: Dyslipidaemia is usually common in obesity, insulin resistance, and type 2 diabetes mellitus. Clinical trials suggest that orange juice may have a positive impact on lipid metabolism and blood lipid profiles; however conflicting results have been reported. Here, we applied a combined untargeted/targeted lipidomic analysis of plasma to examine the impact of orange (Citrus sinensis) juice intake on the lipidome profile of obese and insulin-resistant subjects. METHODS: Twenty-five participants, both sexes, aged 40-60 years, with obesity and insulin resistance (homeostasis model assessment of insulin resistance (HOMA-IR) index >2.71) ingested 400 mL of orange juice 'Pera' (C. sinensis) for 15 d. Cardiometabolic biomarkers, anthropometric parameters, blood pressure, and plasma lipidomic analysis results were assessed at the beginning and end of the intervention. RESULTS: After the 15-d intervention, a significant decrease was observed in the diastolic blood pressure and blood lipid profile. Among plasma lipidomes, 316 lipid molecules were identified, with the triglycerides (TGs) subclass being the most abundant (n = 106). Plasma lipidome profiling revealed a major signature of the intervention; with concentrations of 37 TG species decreasing after intervention. Qualitatively, oleic and linoleic acids were among the most prevalent fatty acids linked to the altered TG species, representing 50% of TG chains. Modulated TG species were positively correlated with total TG and very low-density lipoprotein levels, as well as systolic and diastolic blood pressure. A strong inter-individual trend was observed, wherein, compared with less responsive subjects, the high responsive subjects displayed the highest decrease in the concentrations of altered TG species, as as well as systolic blood pressure (decrease of 10.3 ± 6.8 mmHg) and body weight (decrease of 0.67 ± 0.71 kg). CONCLUSIONS: These findings suggest that orange juice has a positive impact on lipid metabolism, mainly regarding the composition of TG-specific fatty acid chains and cholesterol esters, protecting against insulin resistance. Furthermore, lipidomics may help clarify alterations at the molecular level after an intervention, contributing to improve the evaluation of the link between dyslipidaemia, insulin resistance, and nutrition.

Cytochrome c modification and oligomerization induced by cardiolipin hydroperoxides in a membrane mimetic model.

Cytochrome c (cytc) is a heme protein of 12 kDa that transfers electrons in the mitochondrial respiratory chain. Increased cytc peroxidase activity leads to cardiolipin (CL) oxidation, a hallmark of early apoptosis stage. Here, we aimed to investigate the interaction between cytc with cardiolipin hydroperoxide (CLOOH) in a mimetic mitochondrial membrane. Cytc-CL peroxidase reaction occurred at faster rates with CLOOH than with H2O2. Moreover, liposomes containing CLOOH promoted increased protein aggregation with minor or no release of cytc from the membrane. Dimeric and trimeric cytc species were observed in the first 15 min, followed by increased formation of high-molecular-weight aggregates afterwards. nLC-MS/MS analysis identified several Lys and His residues covalently modified by lipid aldehydes that showed mass increments corresponding to 4-hydroxynonenal (HNE), 4-oxononenal (ONE), hexanoyl, heptenal and octenal addition. Noteworthy, most modifications were observed at Lys and His residues located at A-site (K73, K87, K88), L-site (H26, H33, and K27) membrane binding sites. Further, dityrosine cross-linked peptides were also characterized at residues Y48-Y74, Y48-Y97 and Y74-Y97. Collectively, our findings show that CLOOH causes irreversible protein damage and crosslinking of cytc in the membrane.

Forever panting and forever growing: physiology of Saccharomyces cerevisiae at extremely low oxygen availability in the absence of ergosterol and unsaturated fatty acids.

We sought to investigate how far the growth of Saccharomyces cerevisiae under full anaerobiosis is dependent on the widely used anaerobic growth factors (AGF) ergosterol and oleic acid. A continuous cultivation setup was employed and, even forcing ultrapure N2 gas through an O2 trap upstream of the bioreactor, neither cells from S. cerevisiae CEN.PK113-7D (a lab strain) nor from PE-2 (an industrial strain) washed out after an aerobic-to-anaerobic switch in the absence of AGF. S. cerevisiae PE-2 seemed to cope better than the laboratory strain with this extremely low O2 availability, since it presented higher biomass yield, lower specific rates of glucose consumption and CO2 formation, and higher survival at low pH. Lipid (fatty acid and sterol) composition dramatically altered when cells were grown anaerobically without AGF: saturated fatty acid, squalene and lanosterol contents increased, when compared to either cells grown aerobically or anaerobically with AGF. We concluded that these lipid alterations negatively affect cell viability during exposure to low pH or high ethanol titers.

Redox-triggered events in lipid biology: thiol modification and lipidome alteration in ALS / Eventos redox na biologia dos lipídios: modificação de tióis e alterações do lipidoma em ELA

Lipids encompass a wide range of hydrophobic molecules present in cells. The molecular characteristics of lipids determine their cellular localization and biological function. In general, lipids are regarded as essential components of membranes, as energy reservoir and modulators of signaling pathways linked to cellular metabolism and survival, among others. In mammals, a large part of the lipids are esterified to polyunsaturated fatty acids (PUFAs), especially docosahexaenoic (DHA) and arachidonic (ARA) acids, essential for several physiological processes, including normal brain development. However, PUFAs are very susceptible to oxidation by reactive oxygen species (ROS) generated endogenously. Once oxidized, lipids are able to modify thiol groups of peptides and proteins leading to modulation of signaling pathways and cellular redox balance. In the chapter 1, we investigated the mechanisms involved in modification of thiol groups of peptides and protein by autoxidation products derived from PUFAs. Here, we identified several glutathione (GSH) adducts covalently modified by hydroxy-endoperoxides derived from both DHA and ARA. Detailed inspection of MS/MS spectra of GSH-adducts revealed that GSH and hydroxy-endoperoxides are likely bonded through a sulfur-oxygen chemical bond in a reaction which involves a nucleophilic attack by the thiolate anion. Also, we suggest that the efficiency of modification of thiol by hydroxy-endoperoxides are also dependent of the thiol reactivity, as demonstrated by covalent modification of the most reactive cysteine residue (Cys111) of the antioxidant enzyme Cu,Zn-superoxide dismutase (SOD1). Chemical modifications of thiol groups by hydroxy-endoperoxides may modulate protein aggregation and cellular redox status, yieldingGSH adducts capable to modulate inflammation, as reported for the enzymatically generated counterparts. In the chapter 2, we investigated the role of lipids in amyotrophic lateral sclerosis (ALS), since inflammation and oxidative stress in motor neurons are hallmarks of this neurodegenerative disease. Using an untargeted lipidomics approach based on mass spectrometry coupled to liquid chromatography (UHPLC-MS/MS), we investigated the lipid metabolism in motor cortex and spinal cord tissues of a rodent model of ALS. Analysis of the motor cortex showed that the main lipid alterations were age-dependent and linked to metabolism of sphingolipids. In contrast, the major lipid alterations in the spinal cord were found in ALS symptomatic group, being the metabolism of ceramides, cholesteryl esters and cardiolipin the most affected. According to our findings and data reported in the literature, we proposed a mechanism based on neuroprotection that involves accumulation of cholesteryl esters esterified to PUFAs in astrocytes. Collectively, our findings suggest that lipids play a crucial role in modulation of cellular process linked to thiol metabolism and neurodegeneration

Os lipídeos abrangem uma ampla gama de moléculas hidrofóbicas presentes nas células. As características moleculares dos lipídios determinam sua localização celular e função biológica. Em geral, os lipídios são considerados componentes essenciais de membranas, reservatórios de energia e moduladores de vias de sinalização ligadas ao metabolismo celular, sobrevivência, entre outros. Em mamíferos, grande parte dos lipídios é esterificada em ácidos graxos poli-insaturados (PUFAs), especialmente os ácidos docosahexaenóico (DHA) e araquidônico (ARA), essenciais para vários processos fisiológicos, incluindo o desenvolvimento normal do cérebro. No entanto, os PUFAs são muito suscetíveis à oxidação por espécies reativas de oxigênio (ROS) geradas endogenamente. Uma vez oxidados, lipídios são capazes de modificar grupos tióis de peptídeos e proteínas, levando à modulação das vias de sinalização e alterando o balanço redox celular. No capítulo 1, foram investigados os mecanismos envolvidos na modificação de grupos tióis de peptídeos e proteínas por produtos de auto-oxidação de PUFAs. Com as análises realizadas foi possível identificar vários adutos de glutationa (GSH) covalentemente modificados por endoperóxidos cíclicos derivados de DHA e ARA. Uma análise detalhada dos espectros de MS/MS dos adutos de GSH revelou que GSH e endoperóxidos cíclicos são provavelmente ligados através de uma ligação química de enxofre-oxigênio, em uma reação que envolve um ataque nucleofílico do ânion tiolato. Além disso, sugerimos que a eficiência da modificação do tiol por endoperóxidos cíclicos também é dependente da reatividade do tiol, como demonstrado pela modificação covalente do resíduo de cisteína mais reativo (Cys111) da enzima antioxidante superóxido dismutase 1(SOD1). Modificações químicas de tióis por endoperóxidos cíclicos podem modular a agregação proteica e o status redox celular, produzindo adutos de GSH capazes de modular a inflamação, como relatado para os conjugados de GSH gerados enzimaticamente. No capítulo 2, nós investigamos o papel dos lipídios na esclerose lateral amiotrófica (ALS), uma vez que a inflamação e o estresse oxidativo nos neurônios motores contribuem para o desenvolvimento desta doença neurodegenerativa. Usando uma abordagem lipidômica não direcionada baseada em espectrometria de massa acoplada à cromatografia líquida (UHPLC-MS/MS), nós investigamos o metabolismo lipídico no córtex motor e na medula espinhal de um modelo de ratos com ALS. A análise do córtex motor mostrou que as principais alterações lipídicas foram dependentes da idade e ligadas ao metabolismo dos esfingolipídios. Em contraste, as principais alterações lipídicas na medula espinhal foram encontradas no grupo sintomático da ALS, sendo o metabolismo de ceramidas, ésteres de colesterol e cardiolipinas os mais afetados. De acordo com os resultados obtidos e dados relatados na literatura, propusemos um mecanismo baseado em neuroproteção que envolve o acúmulo de ésteres de colesterol esterificados em PUFAs em astrócitos. Coletivamente, nossos achados sugerem que os lipídios desempenham um papel crucial na modulação de processos celulares ligado à oxidação de tióis e à neurodegeneração