Search Results (770)

Metabolic dysfunction-associated steatotic liver disease (MASLD) is a prevalent global health concern. Although pharmacotherapies such as Resmetirom and semaglutide have recently gained approval by FDA/EMEA, therapeutic options remain limited, necessitating the exploration of novel natural compounds. Our previous research indicated that lycopene exerts protective effects against MASLD; however, its underlying molecular mechanisms remain incompletely understood. The present study aimed to investigate whether lycopene alleviates MASLD by modulating mitophagy, with a focus on the PINK1/Parkin pathway. C57BL/6J mice were fed with high-fat diet for 12 weeks to induce MASLD and daily gavage of lycopene (10/40 mg/kg). In vitro, AML12 cells were treated with lycopene and Mdivi-1 to assess the role of PINK1/Parkin-mediated mitophagy against lipid accumulation, oxidative stress, and apoptosis. The results found that lycopene supplementation significantly ameliorated HFD-induced weight gain, dyslipidemia, hepatic steatosis, pathological liver injury, and elevated serum liver enzymes. It reduced hepatic reactive oxygen species (ROS) overproduction and suppressed the mitochondrial apoptotic pathway, as evidenced by decreased cytochrome c release and caspase cascade activation. Concurrently, lycopene restored ATP levels and mitochondrial membrane potential, improved ultrastructural integrity, and balanced mitochondrial dynamics by downregulating DRP1 and upregulating MFN2 and OPA1. Crucially, lycopene activated PINK1/Parkin-mediated mitophagy, leading to an increased LC3-II/LC3-I ratio and Beclin1 expression, alongside decreased levels of mitochondrial proteins TOM20 and COX IV. In vitro, the lycopene partially reversed the exacerbating effects of Mdivi-1 on lipid accumulation, ROS generation, apoptosis, and the suppression of the PINK1/Parkin pathway. Collectively, lycopene ameliorates MASLD by activating PINK1/Parkin-mediated mitophagy and improving mitochondrial homeostasis, thereby reducing hepatic lipid accumulation and attenuating hepatocyte apoptosis. Full article

Caveolin-1 (CAV1) is a 21 kDa Vesicular Integral-membrane Protein essential for the biogenesis of caveolae, invaginations of the plasma membrane that coordinate membrane trafficking, lipid homeostasis, and signal transduction. CAV1 functions as a scaffolding platform that integrates mechanotransduction, endocytosis, and cellular stress responses, thereby modulating vascular integrity, inflammation, metabolism, and tumorigenesis. To comprehensively understand the phosphorylation landscape of CAV1, global phosphoproteomic datasets and their corresponding experimental metadata were systematically curated and integrated from previously published human cellular studies. The phosphorylation sites with the highest detection frequency across these datasets were considered predominant phosphorylation sites. To assess their functional relevance, phosphosites in other proteins (PsOPs) co-regulated with the predominant CAV1 sites, along with their upstream kinases and high-confidence protein–protein interaction partners, were systematically analyzed. Analysis of global human cellular phosphoproteome datasets revealed that tyrosine 14 (Y14) and serine 37 (S37) of CAV1 are the most frequently detected phosphosites across diverse experimental conditions. Notably, many of the co-regulated proteins obtained were associated with carcinogenesis, apoptosis, and cell cycle regulation, including MET and ERBB2. Our analysis revealed SRC, ABL2, ERBB2, ERBB3, LYN, and TEC as potential upstream kinases of CAV1_Y14, whereas CSNK1E and GRK5 were predicted to regulate CAV1_S37. Considering the challenges associated with site-specific interrogation, we employed a global co-regulation analysis approach to characterize CAV1 phosphorylation dynamics. Our findings reveal that key CAV1 phosphosites modulate oncogenic signaling, cytoskeletal remodeling, and membrane organization, providing novel insights into CAV1-mediated cellular functions and its context-dependent role in tumor progression. Full article

Ceramidases hydrolyze ceramides to fatty acids and sphingolipids, but their role in fungal response to stress remains unclear. We investigated the function of neutral ceramidase (nCDase) response to aromatic fungicide (carvacrol, cuminaldehyde, and isoniazid) stress in Neurospora crassa. Comparative analysis of the wild-type strain, Δnc and OEnc showed that nCDase enhanced fungicide resistance through multiple mechanisms. nCDase improved β-1,3-glucan synthesis (30% increase), decreased membrane permeability, elevated superoxide dismutase and catalase activities, and promoted carotenoid accumulation (50%), which collectively improved stress tolerance. Δnc exhibited disruption of cellular integrity, altered fatty acid profiles (elevated oleic acid, reduced total fatty acids), and increased fungicide sensitivity. Collectively, these findings established that nCDase as a key regulator of cell wall dynamics, lipid homeostasis, and antioxidant defense, thereby facilitating fungal adaptation to abiotic stress. This study identified the role of nCDase in the response to aromatic fungicide stress and laid foundation for inhibiting pathogenic fungi in agricultural production and food preservation. Full article

Phospholipids function as dynamic regulators of plant growth and environmental adaptation, extending well beyond their structural roles in biological membranes. This review synthesizes the phospholipid metabolic network and its regulatory functions in plant physiology. We first describe enzymatic reactions and acyl-chain remodeling in phospholipid biosynthesis, and then examine the interaction between phospholipid metabolism and auxin signaling, focusing on phosphatidic acid (PA) and phosphoinositide phosphate (PIP). These lipid molecules regulate the polarization and vesicular trafficking of PIN-FORMED proteins via endocytosis and phosphorylation-dependent mechanisms, thereby controlling auxin distribution during development and stress adaptation. Particular emphasis is placed on PA, a multifunctional signaling lipid that serves as a central molecular hub. PA coordinates hormonal, stress, and circadian signals by engaging and modulating a broad spectrum of protein targets, including kinases, phosphatases, and transcription factors. We also discuss the emerging and evolutionarily conserved functions of phospholipid signaling in cell fate determination, drawing parallels from mammalian cell reprogramming to the regulation of plant cell totipotency and root patterning. Collectively, these findings underscore the critical role of phospholipid-mediated signaling in converting metabolic and environmental cues into developmental reprogramming, providing novel theoretical and functional frameworks for future research in plant lipid biology. Full article

Doxorubicin (DOX) is widely used in clinical chemotherapy, but its susceptibility to oxidation during the combined treatment with cold atmospheric plasma (CAP) raises concerns regarding its therapeutic efficacy. To improve drug stability and targeted delivery efficiency, this study employed classical molecular dynamics simulations to systematically investigate the mechanisms by which CAP-generated active particles and electric fields influence DOX encapsulation by carbon nanotubes (CNTs) and their transmembrane transport. Within a specific range of active particle concentrations, DOX aggregation is suppressed, enabling its spontaneous entry into CNTs for encapsulation. The CAP-induced electric field further promotes the directional migration of DOX, and once a threshold field strength is reached, the encapsulation efficiency is significantly enhanced. Moreover, an appropriate concentration of active particles can lower this threshold, enabling high encapsulation efficiency at electric field strengths as low as 0.3 V/nm. The introduction of CNTs can reduce the exposure of DOX to active particles, thereby effectively protecting it from CAP-induced oxidation. Regarding transmembrane transport, CAP-induced lipid oxidation decreases membrane structural stability, facilitating the intracellular internalization of CNTs and promoting the release of DOX within target cells. Furthermore, under the combined effects of oxidation and electric fields, the pulling force required for CNT transmembrane transport further decreases, the size of transmembrane pores increases, and the transmembrane delivery of DOX is enhanced. These results demonstrate that, under plasma synergy, CNTs exhibit significant potential in enhancing the targeted delivery of chemotherapeutic agents. This work provides important theoretical support for the application of plasma in targeted cancer therapy and offers new insights for the design of precision cancer treatment strategies. Full article

Group 2 innate lymphoid cells (ILC2s) are tissue-resident immune cells that play a central role in type 2 immunity. Beyond cytokine signaling, they integrate inputs from lipids, nutrients, neuroendocrine mediators, and local metabolic cues, establishing cellular metabolism as a key regulator of their function. Immunometabolism provides a framework to understand how ILC2s adapt to diverse tissue environments such as the lung, adipose tissue, gut, skin, and brain, each defined by distinct nutrient availability, oxygen tension, and inflammatory conditions. Unlike many immune cells that primarily rely on glycolysis, ILC2s dynamically balance glycolysis, fatty acid oxidation (FAO), and oxidative phosphorylation (OXPHOS) depending on activation state and tissue context. Lipids not only serve as energy substrates but also regulate membrane organization, lipid raft–dependent signaling, and the generation of bioactive mediators, including eicosanoids, oxysterols, and sphingolipids. Emerging evidence linking cholesterol biosynthesis, steroid metabolism, and sphingolipid signaling to ILC2 function underscores the importance of lipid-dependent immune regulation. Dysregulation of these pathways contributes to chronic inflammatory diseases such as asthma, metabolic disorders, and fibrosis. Targeting metabolic pathways and checkpoints may therefore offer new strategies to modulate ILC2-driven pathology. This review summarizes current insights into metabolic programs governing ILC2 activation, survival, and plasticity and highlights emerging therapeutic opportunities. Full article

Cells contain an unexpectedly large diversity of lipid molecules. Modern lipidomics studies have revealed that even a single cell type can harbor hundreds to thousands of distinct lipid species that differ in headgroup structure, acyl chain length, and degree of unsaturation. While this remarkable diversity is now well established, its biological significance remains incompletely understood. Why do cells maintain such complex lipidomes? In this review, we examine several conceptual frameworks that may help explain the origin and functional significance of lipid diversity. First, the physical properties of biological membranes impose constraints on lipid composition, as variations in lipid structure influence membrane fluidity, curvature, thickness, and phase behavior. Second, lipids can regulate membrane protein function through specific interactions and through the physical environment of the lipid bilayer. Third, lipid metabolism generates signaling molecules that participate in diverse regulatory pathways. Fourth, lipid metabolic networks continuously remodel membrane composition, producing dynamic lipidomes that can adapt to physiological conditions. Finally, evolutionary processes have shaped membrane lipid composition across different domains of life, suggesting that lipid diversity may reflect long-term adaptation to functional and environmental constraints. Taken together, these perspectives suggest that lipid diversity is unlikely to be a simple byproduct of metabolism. Instead, the cellular lipidome may emerge from the interplay of membrane biophysics, metabolic network architecture, protein regulation, and evolutionary pressures. Understanding why cells contain thousands of lipid species therefore represents an important challenge for modern cell biology and may reveal fundamental principles governing the organization of biological membranes. Full article

Sterols and sphingolipids assemble into specialized membrane microdomains that are essential for membrane function, protein sorting, and signal transduction. Although coordinated regulation between sterol and sphingolipid metabolic pathways has long been recognized, the molecular mechanisms mediating this cross-talk remain incompletely defined. Here, we uncover an unanticipated role for the conserved yeast Orm proteins in controlling sterol and neutral lipid homeostasis. Deletion of ORM1 and ORM2 causes hypersensitivity to sterol biosynthesis inhibitors, accumulation of steryl esters, and an increase in lipid droplet number. Consistent with mutants lacking core neutral lipid hydrolases, orm1Δ orm2Δ cells display a marked defect in neutral lipid mobilization. These phenotypes depend on sphingolipid pathway perturbation but cannot be attributed to sphingolipid accumulation alone. Together, these findings position the Orm proteins as regulatory nodes linking sterol metabolism, lipid droplet dynamics, and sphingolipid biosynthesis. Full article

A series of hexadecylpiperidinium surfactants containing alkyl (PMe-16, PEt-16, PBu-16), benzyl (Benz-16, 1-Benz-3-HP-16, 1-Benz-4-HP-16), and hydroxyl (3-HPMe-16, 4-HPMe-16) substituents in the ring were tested with the nematode Caenorhabditis elegans to investigate the relationship between nematocidal activity and the structural features of surfactants. It was found that increasing the hydrophobicity of the substituent in the surfactant head group reduced the nematocidal activity in the order PMe-16 > PEt-16 > PBu-16 > Benz-16. The lead compound, PMe-16, showed significantly higher activity than the commercial insecticide carbofuran, and was able to induce nearly complete nematode mortality within 24 h at a concentration of 50 μg·mL⁻¹, as well as suppress culture development at concentrations of 25–100 μg·mL⁻¹. All tested piperidinium surfactants inhibited nematode population development at 100 μg·mL⁻¹, while PMe-16 remained effective at concentrations as low as 25 μg·mL⁻¹. The membranotropic properties of the surfactants were evaluated using a turbidimetric method with dipalmitoylphosphatidylcholine (DPPC)-based liposomes as a model of biomembranes. Dynamic light scattering measurements were performed in parallel to assess changes in liposome size and zeta potential as a function of surfactant content, as well as to determine the critical concentration required to induce lipid bilayer destabilization. These results provide indirect evidence of surfactant–membrane interactions. The combinations of piperidinium surfactants and carbofuran showed pronounced synergistic effects, reducing the insecticide dose while maintaining efficacy. Synergy was evaluated using the Bliss independence model and the Highest Single Agent model. The addition of the most active surfactants (PMe-16 and 4-HPMe-16) at 6.25 μg·mL⁻¹ enabled an approximately twofold reduction in the carbofuran dose while maintaining full nematocidal activity. Full article

In oleaginous yeast submerged fermentation, dissolved oxygen (DO) regulates both metabolism and cell morphology. Under oxygen limitation, Trichosporon cutaneum transitions from yeast-form to hyphae-form; the yeast-form morphology is more suitable for lipid production. This study enhanced oxygen transfer via reactor engineering to maintain yeast morphology and improve lipid productivity. Three strategies were assessed: increased agitation/aeration, enriched air supply, and microporous ceramic membrane gas distributor (MCMGD). Fermentation kinetics were analyzed alongside computational fluid dynamics (CFD) simulations of volumetric mass transfer coefficient (k_La), gas holdup, bubble diameter, and flow fields. Conventional strategies only partially alleviated oxygen limitation (maximum 4.47 g/L lipid). Enriched air improved lipid content but induced early myceliation. The MCMGD (1.0 vvm, 150 rpm) shortened fermentation from 150 h to 60 h, achieving 12.06 g/L lipid (49.16% content)—a 2.16-fold lipid concentration increase. Mechanistically, it generated smaller bubbles (1.47 mm vs. 2.54 mm) and higher k_La (0.012 s⁻¹ vs. 0.0055 s⁻¹). CFD revealed improved axial flow, reduced dead zones, and uniform gas holdup, suppressing yeast-to-hyphae shift. By enhancing mass transfer under low shear, the MCMGD ensures adequate oxygenation, maintains productive morphology, and significantly improves lipid production—offering a promising strategy for industrial application. Full article

The emergence of membrane boundaries represents a decisive transition in the origin of life, yet the molecular nature of the earliest abiotic membranes remains uncertain. Existing models based on simple fatty acids, while experimentally tractable, often lack the environmental robustness required under fluctuating prebiotic conditions. Furthermore, the absence of clear pathways linking primitive amphiphiles to later phospholipid systems highlights the need for chemically continuous intermediate frameworks. Here, we explore borate-bridged amphiphile–carbohydrate conjugates as plausible intermediates between simple prebiotic surfactants and modern lipid bilayers. These conjugates arise from low-molecular-weight polyols—including glycerol, butane-1,2,3,4-tetraol, pentane-1,2,3,4,5-pentaol, and hexane-1,2,3,4,5,6-hexitol—reacting with long-chain alkyl ethers and borate species under alkaline conditions, enabling reversible coupling to ribose and other vicinal diol-containing sugars. This chemistry integrates three essential properties for early compartmentalization: hydrolytically robust ether-linked hydrophobic domains, multivalent and highly hydrated headgroups, and environmentally responsive borate coordination. Comparative physicochemical analysis suggests that single-tail alkylglycerol derivatives preferentially form micelles and interfacial films, while di- and tri-tail tetritol and pentitol conjugates favor lamellar assemblies and vesicle formation across realistic prebiotic pH and salinity ranges. Hexitol-based systems, particularly those bearing three hydrophobic chains, may act as membrane-stabilizing components that enhance rigidity and reduce permeability under extreme conditions. We propose that heterogeneous mixtures dominated by two-tail polyol diethers, supplemented by tri-tail stabilizers and surface-active alkylglycerols, could provide mechanically robust, pH-tunable, and sugar-decorated abiotic membranes. Such borate-mediated amphiphiles offer a chemically coherent framework linking carbohydrate stabilization, ether lipid persistence, and dynamic self-assembly, potentially representing a transitional stage in the evolutionary pathway from primitive amphiphilic films to biologically encoded membranes. Full article

Endocrine therapy is the mainstay for estrogen receptor (ER) α-positive breast cancer (BC), yet many patients display acquired resistance. We then screened natural compounds using human ERα-positive BC cells and identified perillyl alcohol (POH), a monoterpene from perilla, that reduces ERα protein levels. Chemoproteome analysis using POH-immobilized nanomagnetic beads revealed adenine nucleotide translocase 2 (ANT2), a mitochondrial inner membrane protein, as a direct target of POH. Molecular dynamics (MD) simulations predicted POH binding to the central pore of ANT2, which functions in ATP transport. ANT2 depletion reduced ERα levels, and public datasets indicate that high ANT2 expression correlates with poor prognosis in ERα-positive BC. POH also inhibited the growth of Tamoxifen- and Fulvestrant-resistant BC cells. RNA sequencing showed that fatty acid elongation-related genes were upregulated in Fulvestrant-resistant cells but downregulated by ANT2 depletion. Both ANT2 depletion and POH treatment led to the accumulation of intracellular lipid droplets in Fulvestrant-resistant cells, consistent with impaired fatty acid elongation. Finally, in silico screening using MD simulations identified venetoclax and nystatin as potential ANT2 pore binders. Both compounds reduced ERα levels in ERα-positive BC cells and increased lipid droplet formation in Fulvestrant-resistant cells. These findings highlight ANT2 as a druggable target against endocrine-resistant BC. Full article

Background: The reliable co-loading of paclitaxel (PTX) and indocyanine green (ICG) into a single lipid nanoparticle (LNP) enables synergistic antitumor delivery but remains challenging due to their distinct physicochemical properties. Methods: This study integrated COSMO-RS calculations, molecular dynamics simulations, and in vitro assays to systematically investigate the effects of lipid composition, drug modification, particle size, and solvent environment on dual-drug loading. Results: This work indicate that DMPS lipid membranes featuring highly polar headgroups and ordered bilayer structures stably bind both ICG and PTX, achieving drug-loading efficiencies (DLEs) of 7.2% and 5.6%, respectively. Carboxylation of PTX enhanced hydrogen bonding with DMPS, while alkyl chain modifications improved membrane insertion, though excessive chain length (e.g., C12) reduced stability due to increased flexibility. Increasing the LNP size from 50 nm to 250 nm raised the DLE of PTX from 4.7% to 8.1%, while sizes beyond 500 nm led to membrane destabilization. The use of 20 vol% ethanol increased total drug loading by 51% by disrupting the hydration shell of ICG and suppressing PTX aggregation; however, ethanol concentrations exceeding 40 vol% intensified drug–solvent competition and weakened membrane binding. Conclusions: This study provides a comprehensive elucidation of the multifactorial regulatory mechanisms underlying dual-drug loading in LNPs, offering a theoretical basis for the rational design of efficient co-delivery systems. Full article

The lateral organization of the plasma membrane (PM) is vital for cellular signaling, yet the specific mechanisms by which the internal cortical actin meshwork templates the organization of the external lipid leaflet remain poorly understood. While established models like the ‘picket-fence’ emphasize physical barriers to diffusion, recent observations of fiber-like “ghost” structures in the distribution of glycosylphosphatidylinositol-anchored proteins (GPI-APs) suggest a more intricate mode of spatial coordination. In this study, we utilize imaging total internal reflection fluorescence correlation spectroscopy (ITIR-FCS) and variable-angle TIRF to resolve whether these filamentous patterns represent genuine membrane-proximal features or optical artifacts of cytosolic transport. Our results demonstrate that these fiber-like tracks are strictly confined to the immediate PM interface and disappear as the evanescent field probes deeper into the cytosol. While the spatial distribution of GPI-APs is templated by the underlying actin meshwork, quantitative diffusion mapping shows that the lateral dynamics of the probe remains largely uniform and is not significantly modulated by these filamentous patterns. By pharmacologically perturbing the actin scaffold and membrane cholesterol, we show that this transbilayer coupling is contingent upon a cholesterol-dependent cytoskeletal pinning mechanism. These findings demonstrate a decoupling of spatial organization and molecular dynamics, providing evidence for how the actin scaffold patterns nanoscale membrane organization without imposing long-range barriers to diffusion. Full article

To explore the seasonal variation patterns of the skin microecology of Altay sheep under transhumant grazing conditions, skin swabs were collected from 60 free-grazing Altay sheep at seasonal transition nodes in the Altay region. Metagenomic sequencing combined with untargeted metabolomics was used to characterize their bacterial community structure, functional pathways, and metabolite profiles. The results showed that the skin microecology of Altay sheep presented obvious seasonal variation patterns. In spring, 35 of the 39 highly abundant bacteria were environmentally derived, five proliferation-related pathways were significantly enriched, and the levels of five metabolites associated with microbial community regulation and skin barrier defense were elevated. In summer, the abundance of three skin symbiotic bacteria increased, the activities of eight pathways mainly related to biofilm formation were significantly enhanced, and the contents of five metabolites primarily associated with membrane lipid homeostasis and selective bacteriostasis increased. In autumn, the abundances of nine radiation-resistant and cold-tolerant strains increased, together with the elevated abundance of two opportunistic pathogens; five repair-related pathways were active, and the levels of four anti-inflammatory and repair-associated metabolites were synchronously increased. In winter, the abundance of two cold-tolerant strains increased, the activities of pathways related to nitrogen metabolism and energy synthesis were enhanced, and one lignan compound was identified as the key metabolite. These findings elucidate the seasonal dynamic patterns of the skin microecology of Altay sheep and provide a theoretical basis for research on the adaptive mechanisms and seasonal health management of Altay sheep and other sheep in alpine regions. Full article