The NP-C gene: a key to pathways of intracellular cholesterol transport.

Elucidation of the pathways for intracellular transport of cholesterol is an important yet elusive goal in cell biology. Analysis of the cellular defects in the human disease Niemann-Pick C (NP-C) is providing insights into this problem. Cholesterol derived from low-density lipoprotein accumulates in lysosomes of NP-C cells, apparently because intracellular movement of such cholesterol is blocked. Identification of the NP-C gene should provide crucial molecular clues to the mechanism of cholesterol transport within cells.

Sites of lipoprotein lipase activity in adipose tissue perfused with chylomicrons. Electron microscope cytochemical study.

Lipoprotein lipase activity was studied in rat parametrial adipose tissue perfused with chylomicrons and in gelatin blocks containing postheparin plasma and chylomicrons. The tissues and blocks were fixed in glutaraldehyde and incubated in 0.035 M CaCl(2)-0.1 M Tris medium (pH 8.3) at 38 degrees C. The doubly labeled chylomicron triglycerides (glycerol-(3)H and palmitate-(14)C) in the tissues and blocks were hydrolyzed during incubation to free fatty acids (FFA) and the FFA remained in the specimens; hydrolysis was inhibited by 0.004 M diethyl paranitrophenyl phosphate (E-600). Incubated blocks and tissue were treated with 0.05 M Pb(NO(3))(2), postfixed in OsO(4), dehydrated with acetone, embedded in Epon, and examined by electron microscopy. The incubated blocks contained electronlucent areas and granular and laminar precipitates at sites of hydrolysis. Similar precipitates were found in incubated tissue, within vacuoles and microvesicles of capillary endothelium, and in the subendothelial space (between the endothelium and pericytes), but not in the capillary lumen or in or near fat cells. The cytochemical reaction was greatly reduced, in blocks and tissues incubated with E-600. It is concluded that plasma glycerides are hydrolyzed by lipoprotein lipase in capillary endothelial cells and in the subendothelial space of adipose tissue and that glycerides across the endothelial cells within a membrane-bounded system.

Effects of lipoprotein lipase on the structure of chylomicrons.

Chylomicrons isolated from rat lymph were complexed with lipoprotein lipase of post-heparin plasma (chylomicrons-LPL) in order to study the effects of lipolysis on the structure of chylomicrons. Triglyceride in the chylomicron core was readily hydrolyzed to free fatty acids (FFA) and glycerol when chylomicrons-LPL were incubated at pH 8.3 in medium containing albumin. Although most of the FFA were immediately released to the medium, some were retained within chylomicrons when FFA-binding sites on albumin were not available. These observations suggest that albumin may have a specific role in the transfer of FFA across the chylomicron surface film. Chylomicrons-LPL assumed many different shapes as they were depleted of triglyceride by the lipolytic action of the enzyme, and total removal of core triglyceride resulted in empty sacks of surface film. The surface film was visualized in sections of OsO(4)-fixed chylomicrons-LPL as a thin electron-opaque line, 25-30 A wide, in areas where the underlying electron-opaque core had been replaced by zones of decreased electron opacity, and in folds of surface film extending outward from chylomicrons partially depleted of core lipid. The findings demonstrate that chylomicrons consist of a core of liquid triglyceride enveloped by a pliable and durable monolayer surface film, and that lipoprotein lipase reduces the triglyceride core without disrupting the surface film.

Lens epithelial cell elongation in the absence of microtubules: evidence for a new effect of colchicine.

Embryonic chick lens epithelial cells cultured in serum-supplemented medium elongated in the absence of microtubules after treatment with the antimicrotubule drug nocodazole. Colchicine, at concentrations lower than those that dissociate microtubules, blocks cell elongation and the associated increase in cell volume. These results indicate that an increase in cell volume, not microtubules, is responsible for lens cell elongation and suggest a previously undescribed effect of colchicine on cell volume regulation.

Niemann-Pick C1 disease gene: homology to mediators of cholesterol homeostasis.

Niemann-Pick type C (NP-C) disease, a fatal neurovisceral disorder, is characterized by lysosomal accumulation of low density lipoprotein (LDL)-derived cholesterol. By positional cloning methods, a gene (NPC1) with insertion, deletion, and missense mutations has been identified in NP-C patients. Transfection of NP-C fibroblasts with wild-type NPC1 cDNA resulted in correction of their excessive lysosomal storage of LDL cholesterol, thereby defining the critical role of NPC1 in regulation of intracellular cholesterol trafficking. The 1278-amino acid NPC1 protein has sequence similarity to the morphogen receptor PATCHED and the putative sterol-sensing regions of SREBP cleavage-activating protein (SCAP) and 3-hydroxy-3-methyl-glutaryl coenzyme A (HMG-CoA) reductase.

Effect of pH on visualization of fatty acids as myelin figures in mouse adipose tissue by freeze-fracture electron microscopy.

We studied the effect of pH on visualization of fatty acids as myelin figures in young mouse epididymal adipose tissue. Fatty acid content of the tissue was increased to 12.4 nmol/mg wet weight by treating the tissue with 380 microM isoproterenol at pH 7.4 for 15 min in the absence of glucose and albumin. Myelin figures were found in freeze-fracture replicas of isoproterenol-treated tissue fixed with glutaraldehyde at pH 7.4 and then incubated and glycerinated at pH 8.1. Myelin figures were seen in replicas as concave or convex laminated sheets and long cylindrical multilamellar structures in fat cells and extracellular space. Myelin figures were sometimes seen in cells extending from the surface of intracellular lipid droplets, the site of lipolysis, to the cell surface and extracellular space. Myelin figures were not found in isoproterenol-treated tissue fixed at pH 7.4 and processed at pH 7.0. Smooth-surfaced droplets, instead, were found in these tissues in the extracellular space. Neither myelin figures nor smooth-surfaced droplets were found in tissues treated with insulin and glucose (to reduce fatty acid content to 1.4 nmol/mg), fixed at pH 7.4 and processed at either pH 8.1 or pH 7.0. Lowering pH of the media to 4.5 during processing of tissues treated with isoproterenol at pH 9.0 caused disappearance of myelin figures and appearance of smooth-surfaced droplets in the extracellular space. Myelin figures were found in replicas of tissue treated with isoproterenol for 15 min at pH 7.4, incubated 10 min at pH 8.4, quick-frozen and then freeze-fractured, indicating that formation of myelin figures was not dependent on glutaraldehyde fixation and glycerol infiltration of the tissue. Our findings show that excess fatty acids in adipose tissue can be visualized as myelin figures if the tissue is exposed to pH 8.1-9.0 and maintained at or above pH 7.4, or as smooth-surfaced droplets if the tissue is processed at pH 7.0 or 4.5. We conclude that myelin figures formed under these conditions are composed primarily of partially ionized fatty acids (acid-soaps), and that the smooth-surfaced droplets in the extracellular space are composed of un-ionized (protonated) fatty acids.

Type C Niemann-Pick disease: dimethyl sulfoxide moderates abnormal LDL-cholesterol processing in mutant fibroblasts.

Biochemical and cytochemical studies have revealed that abnormal processing of low-density-lipoprotein (LDL) cholesterol can be reversed in mutant Niemann-Pick C (NP-C) fibroblasts when 2% dimethyl sulfoxide (DMSO) is added to the culture medium. Both the excessive lysosomal accumulation of LDL cholesterol and the delayed induction of cellular homeostatic responses associated with the uptake of LDL by the mutant cells were substantially reversed by DMSO. DMSO appears to accelerate the intracellular mobilization of LDL-derived cholesterol through effects that may reflect enhanced membrane permeability or cholesterol solubilization.

Sickling of nucleated erythroid precursors from patients with sickle cell anemia.

The pathophysiology of sickle cell anemia is primarily explained in terms of the oxygen-dependent polymerization of sickle hemoglobin (HbS) followed by sickling of erythrocytes. Since the rate and extent of HbS polymerization depend on its intracellular concentration, it has been generally assumed that sickling occurs primarily in mature erythrocytes with their high intracellular hemoglobin concentration. In the present study, we investigated the propensity of nucleated erythroid precursors to undergo sickling; both cultured and fresh marrow-derived erythroid precursors from patients with homozygous sickle cell anemia were studied. The results revealed that upon deoxygenation cultured erythroblasts underwent characteristic morphological deformation in the form of fine, fragile, elongated spicules. Ultrastructural analysis demonstrated highly organized and tightly aligned hemoglobin fibers in the protruded regions. Bone marrow cells examined under partial or complete deoxygenated conditions displayed similar morphological changes. When cultured SS erythroid precursors were exposed to hydroxyurea or butyrate, drugs that may increase fetal hemoglobin (HbF) and inhibit intracellular polymerization, a significant decrease was observed in the propensity of these precursors to undergo sickling, accompanied by a three- to fivefold increase in HbF. These results suggest that, in addition to mature erythrocytes, nucleated erythroid precursors in the bone marrow have the capacity to undergo characteristic sickling as a result of HbS polymerization and may be involved in several aspects of the pathophysiology of sickle cell anemia. Treatment with HbF-stimulating drugs may benefit patients with this disease by inhibiting polymerization-induced sickling of erythroid precursors in the marrow as well as mature erythrocytes in the peripheral blood.

Immunocytochemical evidence that GLUT4 resides in a specialized translocation post-endosomal VAMP2-positive compartment in rat adipose cells in the absence of insulin.

Insulin stimulates glucose transport in rat adipose cells through the translocation of GLUT4 from a poorly defined intracellular compartment to the cell surface. We employed confocal microscopy to determine the in situ localization of GLUT4 relative to vesicle, Golgi, and endosomal proteins in these physiological insulin target cells. Three-dimensional analyses of GLUT4 immunostaining in basal cells revealed an intracellular punctate, patchy distribution both in the perinuclear region and scattered throughout the cytoplasm. VAMP2 closely associates with GLUT4 in many punctate vesicle-like structures. A small fraction of GLUT4 overlaps with TGN38-mannosidase II, gamma-adaptin, and mannose-6-phosphate receptors in the perinuclear region, presumably corresponding to late endosome and trans-Golgi network structures. GLUT4 does not co-localize with transferrin receptors, clathrin, and Igp-120. After insulin treatment, GLUT4 partially redistributes to the cell surface and decreases in the perinuclear area. However, GLUT4 remains co-localized with TGN38-mannosidase II and gamma-adaptin. Therefore, the basal compartment from which GLUT4 is translocated in response to insulin comprises specialized post-endosomal VAMP2-positive vesicles, distinct from the constitutively recycling endosomes. These results are consistent with a kinetic model in which GLUT4 is sequestered through two or more intracellular pools in series.

Microtubules are not required for glucocorticoid receptor mediated gene induction.

Steroid-free glucocorticoid receptors are generally considered to reside in the cytoplasm of cells. After the binding of steroids, the receptors translocate into the nucleus in a manner that has been proposed to involve microtubules. However, some results with inhibitors of microtubule assembly argue to the contrary. In all of these studies, only the whole cell localization of receptors has been examined; the biological activity of these receptors has not been determined. We now report that steroid-induced gene expression is maintained in the absence of intact microtubules. This argues that microtubules are not required for either the nuclear translocation or biological activity of glucocorticoid receptors.

Transport of fatty acids and monoacylglycerols in white and brown adipose tissues.

Long chain fatty acids (FA) and 2-monoacylglycerols (MG) are produced by lipoprotein lipase (LPL) from plasma triacylglycerols (TG) in capillaries of adipose tissue and transported to adipocytes for TG synthesis. It is widely proposed FA may be transported in cells by FA-binding protein. Mode of transport of MG has received little attention. Our findings in tissues and model membranes indicate that FA (as 1:1 acid-soaps) and MG can be transported in vivo by lateral movement in an interfacial continuum (IFC) of the outer leaflets of plasma and intracellular membranes of capillary endothelium and adipocytes. We postulate that FA and MG enter the IFC in capillaries and flow in the IFC across endothelium and extracellular space to sites in adipocytes where MG are hydrolyzed by MG-lipase (MGL) to FA and glycerol, and FA are esterified in endoplasmic reticulum or transferred to inner mitochondrial membrane for oxidation. FA and MG produced by hormone-sensitive lipase also enter the IFC. These MG flow in the IFC to sites of MGL activity, and the FA flow in the IFC to capillaries for transport to other tissues by albumin, or to mitochondria for heat production.

Combined lipase deficiency (cld/cld) in mice affects differently post-translational processing of lipoprotein lipase, hepatic lipase and pancreatic lipase.

Lipoprotein lipase (LPL) and hepatic lipase (HL), which act on plasma lipoproteins, belong to the same gene family as pancreatic lipase. LPL is synthesized in heart, muscle and adipose tissue, while HL is synthesized primarily in liver. LPL is also synthesized in liver of newborn rodents. The active form of LPL is a dimer, whereas that of HL has not been established. Combined lipase deficiency (CLD) is an autosomal recessive mutation (cld) in mice which impairs post-translational processing of LPL and HL. Cld/cld mice have very low LPL and HL activities (< 5% of normal), yet normal pancreatic lipase activity. They develop massive hypertriglyceridemia and die within 3 days after birth. The CLD mutation allows synthesis, glycosylation and dimerization of LPL, but blocks activation and secretion of the lipase. Thus, dimerization per se does not result in production of active LPL. Immunofluorescence studies showed that LPL is retained in endoplasmic reticulum (ER) in cld/cld cells. Translocation of Golgi components to ER by treatment with brefeldin A (BFA) enabled synthesis of active LPL in cultured cld/cld brown adipocytes. Thus, production of inactive LPL in cld/cld cells results from inability of the cells to transport LPL from ER. The CLD mutation allows synthesis and glycosylation of HL, but blocks activation of the lipase. Immunofluorescence studies located HL mostly outside of cells in liver, liver cell cultures and incubated adrenal tissue of normal and cld/cld mice and mostly inside of cells in liver cell cultures and adrenal tissues treated with monensin (to block secretion of protein). These findings demonstrate synthesis and secretion of HL by both liver and adrenal cells of normal and cld/cld mice. Thus, the CLD mutation allows secretion of inactive HL by liver and adrenals. However, it does not block synthesis or secretion of active pancreatic lipase. Our findings indicate that LPL, HL and pancreatic lipase, although closely related, are processed differently.

Differential trafficking of the Niemann-Pick C1 and 2 proteins highlights distinct roles in late endocytic lipid trafficking.

UNLABELLED: The cellular location of Niemann-Pick C2 protein (NPC2) in cultured human fibroblasts and Chinese hamster ovary cells was examined immunocytochemically and in living cells by expression of a functional red fluorescent protein chimeric analogue. RESULTS: NPC2 is present in the lysosomes of both cholesterol-depleted and -replenished cells, unlike Niemann-Pick C1 protein (NPC1) which is recruited to late endosomes only upon uptake of low-density lipoprotein. With mobilization of cholesterol from lysosomes, immunocytochemical detection of NPC2 in lysosomes is greatly diminished, whereas NPC1 remains in the late endosomal compartment. We found a partial overlap in the trafficking and organellar sites of accumulation of NPC2 and NPC1. In living cells, NPC2 traffics with NPC1 in late endosomal tubules. However, in contrast to NPC1, which remains either in late endosomal vesicles and tubules or at the peripheries of cholesterol-laden lysosomes, NPC2 moves into the central core of lysosomes. Glycolipid analysis reveals that, in contrast to null mutant NPC1 cells, which accumulate GM2 ganglioside only at the plasma membrane, with no endocytic storage, absence of NPC2 protein in null mutant NPC2 cells does not block internalization of GM2 into endocytic vesicles. This difference in the cellular distribution of GM2 in NPC1 and NPC2 null mutants is the first report of a variation in the phenotypic expression of these genotypically distinct lesions. CONCLUSION: We speculate that while NPC1 may play a major role in the sorting of glycolipids as well as cholesterol within the late endosomes, NPC2 primarily plays a role in the egress of cholesterol and, potentially, glycolipids from lysosomes. These proteins appear not to be integrated into a tightly bound biological complex, but rather represent separate functional entities that complement each other.

Lipoprotein lipase and fatty acid transport in heart, adipose tissue and mammary gland: immuno and cytochemistry.

Lipoprotein lipase acts at the luminal surface of capillaries to hydrolyze chylomicron triacylglycerol to fatty acids that are transferred across the capillary wall to tissue cells for reesterification into cellular triacylglycerol. The distribution of lipoprotein lipase in capillaries and the origin of the lipase was studies with electron microscopic immunocytochemistry in heart. Fatty acids are ampipathic molecules and can be visualized as myelin figures in sections and freeze fracture replicas of tissue. We used this cytochemical technique to study fatty acid transport between capillaries and parenchymal cells in adipose tissue perfused with chylomicrons and in adipose tissue stimulated with isoproterenol to hydrolyze intracellular triacylglycerol with. Morphological results in mammary gland indicate that incorporation of chylomicron fatty acids into milk triacylglycerol occurs via transport of fatty acids in membranes leaflets to sites of reesterification. Fatty acids would leave the membrane leaflet when they are reesterified into triacylglycerol to locate within the hydrocarbon domain of intracellular lipid droplets to be sexcreted into milk.

Morphological changes in lipid droplets within cells of the duodenal transition zone in suckling rats.

This ultrastructural study compares the lipid droplets within epithelial cells at the bases of the duodenal villi in the transition zone between crypts and the lateral portions of the adjacent villi in newborn rats suckled 24 h, 10 days and 15 days and contrasts with cells in similar locations in newborn unsuckled and weaned rats. The mean diameters and numbers of lipid droplets per field decreased when cells from rats at 10 and 15 days of age were compared to those at 24 h of age. The range of sizes also narrowed. There was cell-to-cell variability in number and in opacity of the lipid droplets. Multiple membranous laminae enclosed the droplets. Cells in similar locations in newborn unsuckled and in weaned rats did not contain lipid droplets. It is concluded that the numbers and sizes of the large lipid droplets within cells in the transition zones at the bases of the villi decrease as cells at the same relative locations mature during suckling and as the infant rats mature.