Project description:<p><strong>INTRODUCTION:</strong> The absolute quantitation of lipids at the lipidome-wide scale is a challenge but plays an important role in the comprehensive study of lipid metabolism. </p><p><strong>OBJECTIVES:</strong> We aim to develop a high-throughput quantitative lipidomics approach to enable the simultaneous identification and absolute quantification of hundreds of lipids in a single experiment. Then, we will systematically characterize lipidome-wide changes in the aging mouse brain and provide a link between aging and disordered lipid homeostasis. </p><p><strong>METHODS:</strong> We created an in-house lipid spectral library, containing 76,361 lipids and 181,300 MS/MS spectra in total, to support accurate lipid identification. Then, we developed a response factor-based approach for the large-scale absolute quantifications of lipids. </p><p><strong>RESULTS:</strong> Using the lipidomics approach, we absolutely quantified 1212 and 864 lipids in human cells and mouse brains, respectively. The quantification accuracy was validated using the traditional approach with a median relative error of 12.6%. We further characterized the lipidome-wide changes in aging mouse brains, and dramatic changes were observed in both glycerophospholipids and sphingolipids. Sphingolipids with longer acyl chains tend to accumulate in aging brains. Membrane-esterified fatty acids demonstrated diverse changes with aging, while most polyunsaturated fatty acids consistently decreased. </p><p><strong>CONCLUSION:</strong> We developed a high-throughput quantitative lipidomics approach and systematically characterized the lipidome-wide changes in aging mouse brains. The results proved a link between aging and disordered lipid homeostasis. </p><p><br></p><p><strong>Mouse brain POS UPLC-MS assay</strong> data is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS562' rel='noopener noreferrer' target='_blank'><strong>MTBLS562</strong></a>. </p><p><strong>Mouse brain NEG UPLC-MS assay</strong> data associated to this study is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS495' rel='noopener noreferrer' target='_blank'><strong>MTBLS495</strong></a>.</p>

Project description:INTRODUCTION: The absolute quantitation of lipids at the lipidome-wide scale is a challenge but plays an important role in the comprehensive study of lipid metabolism. </br> OBJECTIVES: We aim to develop a high-throughput quantitative lipidomics approach to enable the simultaneous identification and absolute quantification of hundreds of lipids in a single experiment. Then, we will systematically characterize lipidome-wide changes in the aging mouse brain and provide a link between aging and disordered lipid homeostasis. </br> METHODS: We created an in-house lipid spectral library, containing 76,361 lipids and 181,300 MS/MS spectra in total, to support accurate lipid identification. Then, we developed a response factor-based approach for the large-scale absolute quantifications of lipids. </br> RESULTS: Using the lipidomics approach, we absolutely quantified 1212 and 864 lipids in human cells and mouse brains, respectively. The quantification accuracy was validated using the traditional approach with a median relative error of 12.6%. We further characterized the lipidome-wide changes in aging mouse brains, and dramatic changes were observed in both glycerophospholipids and sphingolipids. Sphingolipids with longer acyl chains tend to accumulate in aging brains. Membrane-esterified fatty acids demonstrated diverse changes with aging, while most polyunsaturated fatty acids consistently decreased. </br> CONCLUSION: We developed a high-throughput quantitative lipidomics approach and systematically characterized the lipidome-wide changes in aging mouse brains. The results proved a link between aging and disordered lipid homeostasis. </br></br> Mouse brain NEG UPLC-MS assay data is reported in the current study MTBLS495. </br> Mouse brain POS UPLC-MS assay data associated to this study is reported in MTBLS562. </br><br/> Linked Studies: <a href='https://www.ebi.ac.uk/metabolights/MTBLS562' target='_blank'><span class='label label-success'>MTBLS562</span></a>

Project description:Breast milk has shown neurodevelopmental advantages compared to infant formula, especially in IUGR infants, which may relate to the fat source. This study aimed to compare neurodevelopmental outcomes in normal birth weight (NBW) and intrauterine growth restricted (IUGR) piglets fed a formula diet with either a vegetable oil (VEG) or bovine milk fat source (MILK). Results showed that total plasma lipids were increased by feeding the MILK diet. 82% and 11% of lipid species were differentially expressed between dietary groups in plasma and hippocampus, respectively, with slight agreement between the plasma and brain lipidome. The MILK diet was most effective in increasing brain lipid accretion, mainly comprising phospholipids. Absolute regional brain weights, grey and white matter volumes, and behavior and motor function scores were lower in IUGR piglets with no effects of diet. Cognitive function and gene expression profiles were similar for dietary and weight groups, and overall only minor interactive effects between diet and weight were observed. In conclusion, dietary fat source influenced the plasma and to a lesser degree the hippocampal lipidome, but was unable to improve on IUGR induced brain structural and functional impairments.

Project description:Dysregulated lipid metabolism is a prominent feature of prostate cancer that is driven by androgen receptor (AR) signaling. Here we used quantitative mass spectrometry to define the “lipidome” in prostate tumors with matched benign tissues (n=21), independent unmatched tissues (n=47), and primary prostate explants cultured with the clinical AR antagonist enzalutamide (n=43). Significant differences in lipid composition were detected and spatially visualized in tumors compared to matched benign samples. Notably, tumors featured higher proportions of monounsaturated lipids overall and elongated fatty acid chains in phosphatidylinositol and phosphatidylserine lipids. Significant associations between lipid profile and malignancy were validated in unmatched samples, and phospholipid composition was characteristically altered in patient tissues that responded to AR inhibition. Importantly, targeting tumor-related lipid features via inhibition of acetyl-CoA carboxylase 1 significantly reduced cellular proliferation and induced apoptosis in tissue explants (n=13). This first characterization of the prostate cancer lipidome in clinical tissues reveals enhanced fatty acid synthesis, desaturation and elongation as tumor-defining features, with potential for therapeutic targeting.

Project description:Lipids play a crucial role in signalling and metabolism, regulating the development and maintenance of the skeleton. Membrane lipids have been hypothesised to act as intermediates upstream of orphan phosphatase 1 (PHOSPHO1), a major contributor to phosphate generation required for bone mineralisation. Here, we spatially resolve the lipid atlas of the healthy mouse knee and demonstrate the effects of PHOSPHO1 ablation on the growth plate lipidome. Lipids spanning 17 subclasses were mapped across the knee joints of healthy juvenile and adult mice using matrix-assisted laser desorption ionisation imaging mass spectrometry (MALDI-IMS), with annotation supported by shotgun lipidomics. Multivariate analysis identified 96 and 80 lipid ions with differential abundances across joint tissues in juvenile and adult mice respectively. In both ages, marrow was enriched in phospholipid platelet activating factors (PAFs) and related metabolites, cortical bone had a low lipid content, while lysophospholipids were strikingly enriched in the growth plate, an active site of mineralisation and PHOSPHO1 activity. Spatially-resolved profiling of PHOSPHO1-knockout (KO) mice across the resting, proliferating, and hypertrophic growth plate zones revealed 272, 306, and 296 significantly upregulated, and 155, 220 and 190 significantly downregulated features, respectively, relative to wild type (WT) controls. Of note, phosphatidylcholine, lysophosphatidylcholine, sphingomyelin, lysophosphatidylethanolamine and phosphatidylethanolamine derived lipid ions were upregulated in PHOSPHO1-KO versus WT. Our imaging pipeline has established a spatially-resolved lipid signature of joint tissues and has demonstrated that PHOSPHO1 ablation significantly alters the growth plate lipidome, highlighting an essential role of the PHOSPHO1-mediated membrane phospholipid metabolism in lipid and bone homeostasis.

Project description:Lipids comprise a complex mixture of molecules that play central but undercharacterized roles across a wide range of functions such as cell membrane maintenance, energy management, and cell signaling. Here, we describe a comprehensive longitudinal lipidomic profiling approach aiming to provide new physiological insights into aging, diabetes, inflammation, and cytokine regulations. By profiling the plasma lipidome to a depth of more than 800 lipid species across 1,546 samples collected from 109 subjects spanning up to 9 years (3.2 average), we identified a myriad of dysregulated lipid species highly associated with transitions from health to disease. Our data suggest distinct physiological roles of complex lipid subclasses including large and small triacylglycerols (TAG), ester- and ether-linked phosphatidylethanolamines (PE), lysophosphatidylcholines (LPC), and lysophosphatidylethanolamine (LPE). The dynamic changes in the plasma lipidome under the conditions of respiratory viral infections, insulin resistance (IR), and aging indicate a putative role of these different lipids in regulating immune homeostasis in health as well as in acute and chronic inflammation. Moreover, metabolically unhealthy subjects diagnosed with IR show (1) disturbed immune homeostasis and differences in specific lipid-clinical measure associations, (2) altered dynamics for particular complex lipids including TAGs, LPCs PEs, and PCs in response to acute infections, and (3) elevated levels of complex lipids such as TAGs and CEs and accelerated aging, highlighting the importance of context specific interpretation of lipid profiles. Overall, our study exemplifies the power of deep and quantitative lipidomics profiling in conjunction with other omics measures to provide new insights into lipidome dynamics in health and disease.

Project description:Phytoplankton lipids, such as microalgae lipids, are important compounds of increasing interest in bioenergy, food, pharmacy, aquaculture and ecology for their high molecular diversity. There is a taxonomically diverse lipid response under P stress with unresolved questions related to the diversified mechanism behind the lipid responses. A marine microalgae with high EPA content was isolated, named Nannochloropsis sp. PJ12. We reveal a mechanism of phosphorus-induced lipid class remodeling in Nannochloropsis sp. PJ12 based on highly corresponding transcriptome and lipidome data. Phosphorus- deprivation leads to the rapid reduction of phospholipids (PL) and synthesis of the betaine lipids (BL). Phosphorus-complement recovers the content of PL and BL to the original level. The changes are mediated mainly by a glycerophosphoryldiester phosphodiesterases on the transcriptome level. To adapt to low phospholipids, the transcription levels of gene encoding P transporter were upregulated. When Nannochloropsis sp. PJ12 was once again under phosphorus-complement, some of gene encoding P transporter continue to increase on the transcription levels. The novel phospholipid-remodeling scheme opens new avenues for metabolic engineering of lipid composition in algae.

Project description:Lipid synthesis must increase during the cell cycle to double membrane mass, but how insufficient synthesis restricts cell-cycle entry is not understood. Here, we identify a lipid checkpoint in G1 phase of the mammalian cell cycle by using live single-cell imaging, lipidome, and transcriptome analysis in non-transformed cells. We show that synthesis of fatty acids in G1 not only increases lipid mass but extensively shifts the lipid composition to unsaturated phospholipids and neutral lipids. Strikingly, acute lowering of lipid synthesis rapidly activates the PERK/ATF4 endoplasmic reticulum (ER) stress pathway that blocks cell-cycle entry by increasing p21 levels, decreasing Cyclin D levels, and suppressing Retinoblastoma protein phosphorylation. Together, our study identifies a rapid anticipatory ER lipid checkpoint in G1 that prevents cells from starting the cell cycle as long as lipid synthesis is low, thereby preventing mitotic failure and cell death, which are triggered by low lipid synthesis much later in mitosis.

Project description:With an expanding aging population burdened with comorbidities, there is considerable interest in treatments that optimize health in later life. Acarbose (ACA), a drug used clinically to treat Type 2 diabetes (T2DM) can extend mouse lifespan, with greater effect in males than in females. Utilizing a genetically heterogeneous mouse model, we tested the ability of ACA to ameliorate functional, pathological and biochemical changes that occur during aging, and determined which of the effects of age and drug were sex-dependent. In both sexes, ACA prevented age-dependent loss of body mass, in addition to improving grip strength, balance/coordination on an accelerating rotarod, and rotarod endurance. Age-related cardiac hypertrophy was seen only in male mice, and this male-specific aging effect was attenuated by ACA. ACA-sensitive cardiac changes were associated with reduced activation of cardiac growth promoting pathways and decreased abundance of peroxisomal proteins involved in lipid metabolism. ACA further ameliorated age-associated changes in cardiac lipid species, particularly lysophospholipids – changes which have previously been associated with aging, cardiac dysfunction and cardiovascular disease in humans. In the liver, ACA had pronounced effects on lipid handling in both sexes, reducing hepatic lipidosis during aging and shifting the liver lipidome in adulthood, particularly favoring reduced triglyceride accumulation. Our results demonstrate that ACA, already in clinical use for T2DM, has broad-ranging anti-aging effects in multiple tissues, and may have the potential to increase physical function and alter lipid biology to preserve or improve health at older ages.

Project description:Neurons are unique among all human cell types in their high energy demand, long lifespans and rich lipid contents. As such, neurons exhibit unique vulnerability to oxidative stress caused by redox imbalance in aging and neurodegenerative diseases (NDDs). To systematically identify regulators of neuronal survival under oxidative stress and regulators of neuronal redox homeostasis, we conducted multiple survival- and FACS-based genome-wide screens in human iPSC-derived neurons, using our functional genomics toolkit including a previously established CRISPRi approach and a newly developed CRISPRa approach. So far, these are the first genome-wide screens in human neurons. Our results revealed that inhibiting glycosphingolipids (GSLs) degradation by depletion of prosaposin (PSAP) drives the formation of lipofuscins in neurons which leads to iron accumulation and strongly induces ROS production that oxidizing lipids and leads to neuronal ferroptosis under oxidative stress. We also conducted single cell CROP-seq screens that revealed transcriptomic signatures of NDD-associated genes. These datasets are freely available through our open-access database CRISPRbrain.