Quantitative Mapping of Leukemia Cells and Intracellular Lipid Droplets Using 3D Refractive Index Tomography in Flow Cytometry

The expression of apolipoprotein A-V (apoA-V) in hepatoma cells results in homing of this protein to intracellular lipid droplets. When hepatoma cells transfected with a full-length apoA-V-green fluorescent protein fusion protein were cultured in medium that was not supplemented with oleic acid (OA), intracellular lipid droplet size and number were reduced compared with those of cells supplemented with OA. Confocal microscopy studies revealed that apoA-V associates with lipid droplets under both conditions. To define the structural requirements for apoA-V lipid droplet association, hepatoma cells were transfected with a series of C-terminal truncated apoA-V variants. Confocal microscopy analysis revealed that, in a manner similar to mature full-length apoA-V (343 amino acids), truncation variants apoA-V(1-292), apoA-V(1-237), and apoA-V(1-191) associated with lipid droplets, while apoA-V(1-146) did not. Western blot analysis of the relative abundance of apoA-V in cell lysates versus conditioned medium indicated that apoA-V variants associated with lipid droplets were poorly secreted while apoA-V(1-146) was efficiently secreted. Ultracentrifugation of conditioned medium revealed that, unlike full-length apoA-V, which associates with lipoproteins, apoA-V(1-146) was present solely in the lipoprotein-deficient fraction. Deletion of the N-terminal signal peptide from apoA-V resulted in an inability of the protein to be secreted into the medium, although it associated with lipid droplets. Taken together, these data suggest that the C terminus of apoA-V is essential for lipid droplet association in transfected hepatoma cells and lipoprotein association in conditioned medium while the signal peptide is required for extracellular trafficking of this protein.

In terrestrial mammals, stratum corneum lipids derive from two sources: deposition of lamellar body lipids in stratum corneum interstices and excretion of sebaceous lipids onto the skin surface, resulting in a two-compartment ("bricks and mortar") system of lipid-depleted cells surrounded by lipid-enriched intercellular spaces. In contrast, intracellular lipid droplets, normally not present in the epidermis of terrestrial mammals, are prominent in avian and marine mammal epidermis (cetaceans, manatees). We compared the transepidermal water loss, ultrastructure, and lipid biochemistry of the viable epidermis and stratum corneum of pigeon apterium, fledgling (featherless) zebra finches, painted storks, cetaceans, and manatees to those of humans and mice. Marine mammals possess an even more extensive lamellar-body secretory system than do terrestrial mammals; and lamellar-body contents, as in terrestrials, are secreted into the stratum corneum interstices. In cetaceans, however, glycolipids, but not ceramides, persist into the stratum corneum; whereas in manatees, glycolipids are replaced by ceramides, as in terrestrial mammals. Acylglucosylceramides, thought to be critical for lamellar-body deposition and barrier function in terrestrial mammals, are present in manatees but virtually absent in cetaceans, a finding that indicates that they are not obligate constituents of lamellar-body-derived membrane structures. Moreover, cetaceans do not elaborate the very long-chain, saturated N-acyl fatty acids that abound in terrestrial mammalian acylglucosylceramides. Furthermore, cold-water marine mammals generate large, intracellular neutral lipid droplets not found in terrestrial and warm-water marine mammals; these lipid droplets persist into the stratum corneum, suggesting thermogenesis, flotation, and/or cryoprotectant functions. Avians generate distinctive multigranular bodies that may be secreted into the intercellular spaces under xerotic conditions, as in zebra fledglings; ordinarily, however, the internal lamellae and limiting membranes deteriorate, generating intracellular neutral lipid droplets. The sphingolipid composition of avian stratum corneum is intermediate between terrestrials and cetaceans (approximately equal to 50% glycolipids), with triglycerides present in abundance. In the midstratum corneum of avians, neutral lipid droplets are released into the interstices, forming a large extracellular, lipid-enriched compartment, surrounding wafer-thin corneocytes, with a paucity of both lipid and keratin ("plates-and-mortar" rather than the "bricks-and-mortar" of mammals).(ABSTRACT TRUNCATED AT 400 WORDS)

Caveolins form plasmalemnal invaginated caveolae. They also locate around intracellular lipid droplets but their role in this location remains unclear. By studying primary adipocytes that highly express caveolin-1, we characterized the impact of caveolin-1 deficiency on lipid droplet proteome and lipidome. We identified several missing proteins on the lipid droplet surface of caveolin-deficient adipocytes and showed that the caveolin-1 lipid droplet pool is organized as multi-protein complexes containing cavin-1, with similar dynamics as those found in caveolae. On the lipid side, caveolin deficiency did not qualitatively alter neutral lipids in lipid droplet, but significantly reduced the relative abundance of surface phospholipid species: phosphatidylserine and lysophospholipids. Caveolin-deficient adipocytes can form only small lipid droplets, suggesting that the caveolin-lipid droplet pool might be involved in lipid droplet size regulation. Accordingly, we show that caveolin-1 concentration on adipocyte lipid droplets positively correlated with lipid droplet size in obese rodent models and human adipocytes. Moreover, rescue experiments by caveolin- green fluorescent protein in caveolin-deficient cells exposed to fatty acid overload demonstrated that caveolin-coated lipid droplets were able to grow larger than caveolin-devoid lipid droplets. Altogether, these data demonstrate that the lipid droplet-caveolin pool impacts on phospholipid and protein surface composition of lipid droplets and suggest a functional role on lipid droplet expandability.

Glioblastoma (GBM) is the most common and aggressive glioma subtype in adults, characterized by disrupted lipid homeostasis. The accumulation of lipid droplets (LDs) is involved in the actin cytoskeleton remodeling in different types of cells, the intracellular fibroblast growth factor 1 (FGF1) plays an important role in this process. The stability of cytoskeleton is crucial for the proliferation, invasion and other malignant behavior of GBM. The synaptic gyrus protein 1 (synaptogyrin 1, SYNGR1) is closely correlated with the progression of various tumours, but there have been no reports of research in the field of glioma. This research was conducted to investigate whether the overexpression of SYNGR1 was involved in regulating the malignant biological behaviour of GBM cells and its potential regulatory mechanism, especially whether the LDs accumulation is involved in the remodeling of the actin cytoskeleton in GBM cells. The UCSC Xena database and GEPIA database were used to analyze the correlation between the expression level of SYNGR1 and the survival time of glioma patients. Engineering Lentiviruses were used to establish cells with stable overexpression of SYNGR1, FGF1, or both. The proliferation, invasion, and cytoskeleton of glioma cells (U251, LN229, U118) were detected by cell counting kit-8 (CCK8), 5-ethynyl-2'-deoxyuridine (EdU), immunofluorescence(IF), colony formation, adhesion, and transwell assays. Intracellular LDs were detected by the lipid droplet red fluorescence assay with Nile red. The cell cycle distribution and apoptosis rate of the cells were assessed using flow cytometry analysis. Bioinformatics analysis, IF, RNA sequencing, and western blot analysis were used to measure the expression levels of target proteins. The protein from HA and HT22 cell lines served as control was detected by western blot analysis. The Gl261 cell line and C57BL/6 mouse were used to construct C57BL/6 mouse glioblastoma model. Animal MRI was used to examine tumor size. SYNGR1 expression was significantly reduced in GBM. Overexpression of SYNGR1 significantly inhibited the LDs accumulation, proliferation, invasion, adhesion, and other malignant processes in GBM cells in vitro. Moreover, SYNGRI overexpression inhibited the growth of intracranial gliomas in vivo and prolonged survival of C57BL/6 model mice. Mechanistic exploration revealed that the overexpression of SYNGR1 had an antiglioma effect by inhibiting the LDs accumulation and remodeling the cytoskeleton via the downregulation of the intracellular FGF1, while FGF1 overexpression could reverse the antiglioma effect of SYNGR1. The intracellular FGF1 played an important role in maintaining the homeostasis of LDs and the actin cytoskeleton, which promoted the malignant progression of GBM cells. Engineering overexpressing SYNGR1 could effectively inhibit the malignant biological behaviors, such as the proliferation, adhesion, and invasion, as well as promote the apoptosis of glioma cells by suppressing the intracellular FGF1-mediated LDs accumulation and cytoskeleton remodeling.

In steroidogenesis, cholesterol‐ the precursor substrate molecule for all steroid hormones is central and the framework of steroidogenesis across steroidogenic cells is constructed around it— including its cellular uptake, storage in intracellular lipid droplets, mobilization upon steroidogenic stimulation, and finally, its transport to the mitochondria where cholesterol is converted to pregnenolone by the P450 side chain cleavage enzyme. Thus, cholesterol and the mitochondria are highly interconnected in all steroidogenic cells. Moreover, accruing evidence suggests that autophagy and mitochondrial dynamics are important cellular events in the regulation of trophic hormone‐induced cholesterol homeostasis and steroidogenesis. However, a potential role of cholesterol in the regulation of steroidogenic events and factors remain unexplored. We tested the hypothesis that cholesterol plays a role in the regulation of cell‐intrinsic factors and events involving steroidogenesis. We used an intermediary approach to investigate the role of cholesterol in the regulation of steroidogenesis in different steroidogenic cell types such as MA‐10 cells (a murine Leydig cell line), BeWo cells (placental cell line) producing different steroid hormones. Steroidogenic cells were cultured in a lipoprotein‐depleted medium that leads to the depletion of the intracellular cholesterol pool and lipid droplets. Furthermore, cholesterol deprivation induced steroidogenic events. To get a snapshot of cholesterol deprived (CD)‐induced changes in lipid droplets, autophagy, and mitochondrial dynamics at an ultrastructural level we analyzed steroidogenic cells using transmission electron microscopy. As expected, cholesterol deprivation resulted in the depletion or loss of intracellular lipid droplets and the cholesterol pool across steroidogenic cell lines. Moreover, a difference in autophagy‐related structural changes was observed between cells cultured under the normal and CD conditions. In general, the structural characteristics of autophagy were more apparent in the CD group when compared with the normal control group across different steroidogenic cell types. Moreover, a change in mitochondrial shape was observed between the cells from two groups. For instance, the elongated or tubular mitochondria showing signs of mitochondrial dynamics (fusion or fission) were more common in the CD experimental group. Importantly, an increase in lysosome size and numbers were consistently found in cells under CD conditions which inversely correlated with the depletion of lipid droplets and the cholesterol pool, suggesting a compensatory increase in cholesterol mobilization. Taken together, this data suggests that cholesterol indeed plays a role in the regulation of autophagy and mitochondrial dynamics across steroidogenic cells in a context‐dependent manner. Such effects of cholesterol deprivation on autophagy and mitochondrial dynamics were not observed in the non‐steroidogenic cells such as HepG2 (human hepatoma cells) and H4IIE (rat hepatoma cells), indicating that cholesterol insufficiency‐induced changes in steroidogenic cells are specific to steroidogenesis. Thus, we unraveled this previously unknown role of cholesterol in steroidogenesis beyond being a mere substrate for steroid hormones. The implications of our findings are broad and offer new insights into trophic hormone‐dependent and independent steroidogenesis during development, as well as in health and disease.

Based on data developed with the use of isolated lipid droplets from neonatal rat lung lipofibroblasts, we speculated previously that the droplet coat protein, adipose differentiation-related protein (ADFP), mediated the transfer of lipids into type 2 lung epithelial cells for the production of surfactant phospholipids. The present studies were designed to test the role of ADFP in this transfer with the use of ADFP-coated lipid droplets from CHO fibroblast cells and a cultured human lung epithelial cell line. We found no role for ADFP in the lipid transfer and conclude that a lipase associated with the lipid droplets hydrolyzes their core triacylglycerols, releasing fatty acids that are taken up by the epithelial cells.

Apolipoprotein A-V (apoA-V) plays a key role in the regulation of triglyceride (TG) metabolism. Given the very low concentration of apoA-V in plasma, we hypothesized that apoA-V may influence plasma TG levels by affecting the assembly and/or secretion of apoB-containing lipoproteins. When apoA-V was overexpressed in cultured Hep3B cells, neither the amount of apoB secreted nor the density distribution of apoB-containing lipoproteins was affected. Fluorescence microscopy and cell lysate immunoprecipitation studies revealed that apoA-V is not associated with apoB intracellularly, yet immunoprecipitation of apoA-V from the cell culture medium resulted in coprecipitation of apoB. These data suggest that the apoA-V association with apoB-containing lipoproteins is a postsecretory event. Confocal fluorescence microscopy revealed the presence of apoA-V in distinct cellular structures. Based on Nile Red staining, we identified these structures to be intracellular lipid droplets. These data suggest that apoA-V has a unique association with cellular lipids and, therefore, may be involved in the storage or mobilization of intracellular lipids.

The ultrastructure of the skin of four cetacean species, bottlenose dolphin (Tursiops truncatus) long-finned pilot whale (Globicephala melaena), humpback whale (Megaptera novaeangliae), and fin whale (Balaenoptera physalus) was investigated with particular reference to epidermal lipid. It has already been established that massive lipid reservoirs exist in whales, that the biochemical structures of cetacean lipids are unique, and that unusual intracellular lipid droplets appear in the epidermis. We report here some novel findings on scanning electron microscopic morphology of epidermal lipid, and on its ultrastructural morphology in general and specialized integumentary sites, including species not previously investigated. The intracellular epidermal lipid droplets were more extensive than lamellar body-derived intercellular lipid which is within the interstices of stratum externum cells. The intracellular droplets were spherical, highly variable in size ranging from 0.24 micron to 3.0 microns in diameter, appeared singly or were aggregated in cytoplasmic cavitations, and often were closely associated with epidermal cell nuclei. Evidence for exocytosis of the intracellular droplets was not observed. Significant numbers of intracellular lipid droplets are not observed in the epidermis of terrestrial mammals, so their presence is one of several aquatic specializations of the cetacean integument. Its full significance remains obscure, but it is more probably associated with epidermal cell metabolism than with secretion of lipid.

IntroductionDysregulated immune homeostasis is implicated in atherosclerosis. Monocytes are described as inert innate immune cells that respond to vascular and inflammatory cues to extravasate into the intima then differentiate into...

Association of Globular β-Actin with Intracellular Lipid Droplets in Rat Adrenocortical Cells and Adipocytes

Introduction: Adrenocortical Carcinoma (ACC) is a rare aggressive cancer which carries a poor prognosis. Adjuvant mitotane improves survival but is limited by poor response rates and resistance following tumour recurrence. Mitotane’s efficacy has been attributed to intracellular accumulation of toxic free cholesterol (FC) predominantly through inhibition of cholesterol storage through SOAT1. Yet SOAT1 specific inhibitors demonstrate inferior efficacy to mitotane in inducing ACC cell death. We hypothesize that mitotane’s efficacy to induce toxic FC accumulation in ACC cells is also mediated through enhanced breakdown of stored cholesterol within intracellular lipid droplets (LDs). Methodology: ATCC-H295R (mitotane sensitive) and MUC-1 (mitotane resistant) ACC cells were evaluated for neutral lipid content using BODIPY493/503 under baseline and cholesterol loaded conditions using Amnis ImageStream, additionally cells were treated with mitotane (H295R - 20, 40, 50µM; MUC1 - 50, 100, 200µM) for 6hr. Analysis of LDs using CE-BODIPY and FA-BODIPY identified cholesterol ester (CE) and triacylglycerol (TAG)-containing LDs, respectively. Lipid droplet-associated proteins (LDAPs) Perilipin (PLIN) 1–4 and hormone sensitive lipase (HSL) were evaluated using western blotting and PCR. Lipid uptake receptors; SRB1, LDLR, LRP1 and CD36 were measured by flow cytometry. Results: Mitotane treatment, within therapeutic range, decreased staining for LDs significantly in H295R. This was also reflected by decreased expression of LDAPs, PLIN1 and PLIN3. The decrease in H295R LDs was associated with increased activation of HSL (pHSL and LIPE). However, this effect was only evident in MUC-1 at supratherapeutic mitotane (200µM). H295R and MUC-1 demonstrated similar overall LD numbers at baseline and under cholesterol supplementation. Expression of PLIN3 was high in both cell lines, while PLIN1, PLIN2 and PLIN4 demonstrated distinct LD profiles in each. Investigation of LD content showed that H295R preferentially store CEs while MUC-1 store only TAG, irrespective of cholesterol-loading. Mitotane treatment significantly reduces both CE and TAG LDs in H295R and MUC-1. Expression of lipid uptake receptors also demonstrated significant variability between cell lines including SRB1 and LRP1. Conclusion: We highlight that lipolysis through LD breakdown and activation of HSL represents a putative additional mechanism for mitotane induced FC cytotoxicity in ACC. We also demonstrate significant differences in cholesterol handling and LDAPs between mitotane sensitive and mitotane resistant models, in particular, the absence of CE LDs in MUC-1. We therefore propose a mechanism of resistance to mitotane through absent CE storage. Further understanding of cholesterol and lipid handling in ACC offers novel therapeutic exploitation, especially in the setting of mitotane resistant disease.

Lipid droplets (LD) consist of accumulations of triacylglycerols and have been proposed to be markers of ischaemic but viable tissue. Previous studies have described the presence of LD in myocardium surviving an acute coronary occlusion. We investigated whether LD may be protective against cell death secondary to ischaemia-reperfusion injury. The addition of oleate-bovine serum albumin complex to freshly isolated adult rat cardiomyocytes or to HL-1 cells resulted in the accumulation of intracellular LD detectable by fluorescence microscopy, flow cytometry and (1)H-nuclear magnetic resonance spectroscopy. Simulated ischaemia-reperfusion of HL-1 cells (respiratory inhibition at pH 6.4 followed by 30 min of reperfusion) resulted in significant cell death (29.7+/-2.6% of total lactate dehydrogenase release). However, cell death was significantly attenuated in cells containing LD (40% reduction in LDH release compared with control cells, P=0.02). The magnitude of LD accumulation was inversely correlated (r(2)=0.68, P=0.0003) with cell death. The protection associated with intracellular LD was not a direct effect of the fatty acids used to induce their formation, because oleate added 30 min before ischaemia, during ischaemia or during reperfusion did not form LD and did not protect against cell death. Increasing the concentration of free oleate during reperfusion progressively decreased the protection afforded by LD. HL-1 cells labelled with fluo-4, a Ca(2+)-sensitive fluorochrome, fluorescence within LD areas increased more throughout simulated ischaemia and reperfusion than in the cytosolic LD-free areas of the same cells. As a consequence, cells with LD showed less cytosolic Ca(2+) overload than control cells. These results suggest that LD exert a protective effect during ischaemia-reperfusion by sequestering free fatty acids and Ca(2+).

Intracellular neutral lipid storage droplets are essential organelles of eukaryotic cells, yet little is known about the proteins at their surfaces or about the amino acid sequences that target proteins to these storage droplets. The mammalian proteins Perilipin, ADRP, and TIP47 share extensive amino acid sequence similarity, suggesting a common function. However, while Perilipin and ADRP localize exclusively to neutral lipid storage droplets, an association of TIP47 with intracellular lipid droplets has been controversial. We now show that GFP-tagged TIP47 co-localizes with isolated intracellular lipid droplets. We have also detected a close juxtaposition of TIP47 with the surfaces of lipid storage droplets using antibodies that specifically recognize TIP47, further indicating that TIP47 associates with intracellular lipid storage droplets. Finally, we show that related proteins from species as diverse as Drosophila and Dictyostelium can also target mammalian or Drosophila lipid droplet surfaces in vivo. Thus, sequence and/or structural elements within this evolutionarily ancient protein family are necessary and sufficient to direct association to heterologous intracellular lipid droplet surfaces, strongly indicating that they have a common function for lipid deposition and/or mobilization.

Isolation and Characterization of Intracellular Lipid Droplets from Bovine Mammary Tissue

The adipose differentiation-related protein (ADFP)/adipophilin belongs to a family of PAT (for perilipin, ADFP, and TIP47) proteins that associate on the surface of lipid droplets (LDs). Except for LD association, a clear role for ADFP has not been found. We demonstrate that ADFP is transcriptionally regulated by peroxisome proliferator-activated receptor alpha (PPARalpha) in mouse liver and rat and human hepatoma cells through a highly conserved direct repeat-1(DR-1) element. Although the ADFP mRNA is highly increased by a synthetic PPARalpha agonist, the ADFP protein is only substantially increased in cells containing LDs, such as hepatocytes incubated with fatty acids, and in livers of fasted mice. ADFP is induced by fasting even in the absence of a functional PPARalpha, in marked contrast to the PPARalpha target gene acyl-coenzyme A oxidase-1. Activation of LXRs, which stimulates LD formation through the activation of lipogenesis, does not affect ADFP mRNA levels. TIP47, another PAT member known to be expressed in liver, was unaffected by all treatments. This constitutively expressed PAT member seems to be less transcriptionally regulated than ADFP. These observations suggest that ADFP is primarily a fasting-induced protein in liver that coats the newly synthesized triacylglycerol-containing LDs formed during fasting.