Your search keyword '"R. J. Raggers"' showing total 10 results

1. Upregulation of the expression of endogenous Mdr1 P-glycoprotein enhances lipid translocation in MDCK cells transfected with human MRP2

Author

Gerrit van Meer, R. J. Raggers, Ilse M. C. Vogels, Cell Biology and Histology, Membraan enzymologie, Universiteit Utrecht, and Dep Scheikunde

Subjects

Histology, Blotting, Western, ATP-binding cassette transporter, Glucosylceramides, Transfection, physiological processes, Cell Line, Downregulation and upregulation, Lipid translocation, polycyclic compounds, Animals, Humans, ATP Binding Cassette Transporter, Subfamily B, Member 1, neoplasms, Molecular Biology, Lipid Transport, P-glycoprotein, Oxadiazoles, biology, Multidrug resistance-associated protein 2, Cell Polarity, Membrane Transport Proteins, Biological Transport, Cell Biology, Apical membrane, Lipid Metabolism, Molecular biology, Multidrug Resistance-Associated Protein 2, Up-Regulation, Cell biology, Medical Laboratory Technology, biology.protein, Multidrug Resistance-Associated Proteins

Abstract

Various ABC transporters can translocate lipid molecules from the cytoplasmic into the exoplasmic leaflet of the plasma membrane bilayer. Two of these, MDR1 P-glycoprotein (Pgp) and MRP1, are multidrug transporters responsible for the resistance of various cancers against chemotherapy. We wanted to study whether MRP2, an ABC transporter of the bile canalicular membrane with a substrate specificity very similar to that of MRP1, is capable of translocating lipids. The translocation of short-chain lipids across the apical membrane of MDCK cells transfected with MRP2 was significantly higher than that in untransfected controls. However, the characteristics of the lipid translocation were similar to substrate transport by MDR1 and not MRP2: transport was strongly inhibited by classic MDR1 Pgp inhibitors, was independent of cellular glutathione, and was insensitive to a drug known to inhibit MRP2 activity. When tested by immunoblot, the MRP2-transfected cells expressed high levels of MRP2 but also of endogenous Mdr1. The expression of Mdr1 was unstable during maintenance of the cell line and correlated with the rate of lipid translocation across the apical membrane. We conclude that the observed increase in lipid transport in the MDCK cells transfected with MRP2 is the consequence of the upregulation of the expression of endogenous Mdr1 and that careful characterization of endogenous Mdr1 expression is needed in studies aimed to identify substrates of plasma membrane transporters.

Published

2001

2. The Organizing Potential of Sphingolipids in Intracellular Membrane Transport

Author

R. J. Raggers, Joost C. M. Holthuis, Hein Sprong, Gerrit van Meer, Thomas Günther Pomorski, Membraan enzymologie, Membrane Enzymology, and Dep Scheikunde

Subjects

Sphingolipids, Molecular Structure, Physiology, Endocytic cycle, Cell Polarity, Golgi Apparatus, Intracellular Membranes, General Medicine, Biology, Sphingolipid, Intracellular membrane, Cell biology, Vesicular transport protein, Protein Transport, Membrane Microdomains, Membrane, International, Physiology (medical), Animals, Humans, lipids (amino acids, peptides, and proteins), Molecular Biology, Lipid raft, Secretory pathway, Signal Transduction

Abstract

Eukaryotes are characterized by endomembranes that are connected by vesicular transport along secretory and endocytic pathways. The compositional differences between the various cellular membranes are maintained by sorting events, and it has long been believed that sorting is based solely on protein-protein interactions. However, the central sorting station along the secretory pathway is the Golgi apparatus, and this is the site of synthesis of the sphingolipids. Sphingolipids are essential for eukaryotic life, and this review ascribes the sorting power of the Golgi to its capability to act as a distillation apparatus for sphingolipids and cholesterol. As Golgi cisternae mature, ongoing sphingolipid synthesis attracts endoplasmic reticulum-derived cholesterol and drives a fluid-fluid lipid phase separation that segregates sphingolipids and sterols from unsaturated glycerolipids into lateral domains. While sphingolipid domains move forward, unsaturated glycerolipids are retrieved by recycling vesicles budding from the sphingolipid-poor environment. We hypothesize that by this mechanism, the composition of the sphingolipid domains, and the surrounding membrane changes along the cis- trans axis. At the same time the membrane thickens. These features are recognized by a number of membrane proteins that as a consequence of partitioning between domain and environment follow the domains but can enter recycling vesicles at any stage of the pathway. The interplay between protein- and lipid-mediated sorting is discussed.

Published

2001

3. Lipid Traffic: The ABC of Transbilayer Movement

Author

R. J. Raggers, G. van Meer, Nanette Kälin, Joost C. M. Holthuis, and Thomas Günther Pomorski

Subjects

Protein family, Cholesterol, Membrane lipids, Peripheral membrane protein, Biological membrane, ATP-binding cassette transporter, Cell Biology, Biology, Biochemistry, Cell biology, chemistry.chemical_compound, Membrane, chemistry, Structural Biology, Genetics, lipids (amino acids, peptides, and proteins), Lipid bilayer, Molecular Biology

Abstract

Membrane lipids do not spontaneously exchange between the two leaflets of lipid bilayers because the polar headgroups cannot cross the hydrophobic membrane interior. Cellular membranes, notably eukaryotic plasma membranes, are equipped with special proteins that actively translocate lipids from one leaflet to the other. In addition, cellular membranes contain proteins that facilitate a passive equilibration of lipids between the two membrane halves. In recent years, a growing number of proteins have been put forward as lipid translocators or facilitators. Unexpectedly, some of these appear to be required for efficient translocation of lipids lacking bulky headgroups, like cholesterol and fatty acids. The candidate lipid translocators identified so far belong to large protein families whose other members include pumps for amphiphilic molecules like bile salts and drugs.

Published

2000

4. Lipid traffic: the ABC of transbilayer movement

Author

R J, Raggers, T, Pomorski, J C, Holthuis, N, Kälin, and G, van Meer

Subjects

Adenosine Triphosphatases, Models, Molecular, Chemical Phenomena, Molecular Structure, Chemistry, Physical, Fatty Acids, Lipid Bilayers, Biological Transport, Active, Golgi Apparatus, Membrane Proteins, Intracellular Membranes, Endoplasmic Reticulum, Models, Biological, Membrane Lipids, Adenosine Triphosphate, Cholesterol, Multigene Family, Animals, Humans, ATP-Binding Cassette Transporters, ATP Binding Cassette Transporter, Subfamily B, Member 1, Phospholipid Transfer Proteins, Carrier Proteins

Abstract

Membrane lipids do not spontaneously exchange between the two leaflets of lipid bilayers because the polar headgroups cannot cross the hydrophobic membrane interior. Cellular membranes, notably eukaryotic plasma membranes, are equipped with special proteins that actively translocate lipids from one leaflet to the other. In addition, cellular membranes contain proteins that facilitate a passive equilibration of lipids between the two membrane halves. In recent years, a growing number of proteins have been put forward as lipid translocators or facilitators. Unexpectedly, some of these appear to be required for efficient translocation of lipids lacking bulky headgroups, like cholesterol and fatty acids. The candidate lipid translocators identified so far belong to large protein families whose other members include pumps for amphiphilic molecules like bile salts and drugs.

Published

2001

5. Assays for transmembrane movement of sphingolipids

Author

D J, Sillence, R J, Raggers, and G, van Meer

Subjects

Sphingolipids, Glycoside Hydrolases, Cell Membrane, Lipid Bilayers, Neuraminidase, Biological Transport, Intracellular Membranes, Galactose Oxidase, Cyclic N-Oxides, Spectrometry, Fluorescence, Sphingomyelin Phosphodiesterase, Gangliosides, Animals, Glucosylceramidase, Spin Labels, Carrier Proteins, Fluorescent Dyes

Published

2000

6. Assay for the transbilayer distribution of glycolipids; selective oxidation of glucosylceramide to glucuronylceramide by TEMPO nitroxyl radicals

Author

R. J. Raggers, Daniel J. Sillence, G. van Meer, David C. A. Neville, David Harvey, Membrane Enzymology, Universiteit Utrecht, and Dep Scheikunde

Subjects

Phosphatidylethanolamine, Nitroxide mediated radical polymerization, Liposome, lipid asymmetry, glycosphingolipid, Nitrosonium, Bilayer, Vesicle, Cell Biology, QD415-436, Biochemistry, behavioral disciplines and activities, humanities, chemistry.chemical_compound, Endocrinology, Membrane, chemistry, ABC transporters, Polymer chemistry, Organic chemistry, Lipid bilayer

Abstract

In the present study, 2,2,6,6-tetramethylpiperidinooxy nitroxide (TEMPO) has been applied successfully to discriminate between glucosylceramide in the outer and inner leaflets of closed membrane bilayers. The nitroxyl radicals TEMPO and carboxy-TEMPO, once oxidized to nitrosonium ions, are capable of oxidizing residues that contain primary hydroxyl and amino groups. When applied to radiolabeled glucosylceramide in liposomes, oxidation with TEMPO led to an oxidized product that was easily separated from the original lipid by thin-layer chromatography, and that was identified by mass spectrometric analysis as the corresponding acid glucuronylceramide. To test whether oxidation was confined to the external leaflet, TEMPO was applied to large unilamellar vesicles (LUVs) consisting of egg phosphatidylcholine–egg phosphatidylethanolamine–cholesterol 55:5:40 (mol/mol). TEMPO oxidized most radiolabeled phosphatidylethanolamine, whereas carboxy-TEMPO oxidized only half. Hydrolysis by phospholipase A2 confirmed that 50% of the phosphatidylethanolamine was accessible in the external bilayer leaflet, suggesting that TEMPO penetrated the lipid bilayer and carboxy-TEMPO did not. When applied to LUVs containing

Published

2000

7. Assays for Transmembrane Movement of Sphingolipids

Author

R. J. Raggers, Daniel J. Sillence, and G. van Meer

Subjects

Membrane, Biochemistry, Cellular Assay, Bilayer, lipids (amino acids, peptides, and proteins), Biology, Lipid bilayer, Endocytosis, Sphingolipid, Exocytosis, Transmembrane protein

Abstract

This chapter compares the available techniques to study the transmembrane distribution of sphingolipids, and describe the requirements that these assays should meet in order to be applicable to measurements of transbilayer mobility. Translocation activity of a particular protein can then be tested by transfection into a cellular assay system, or by reconstitution into model membranes. To determine transmembrane movement of a sphingolipid, an assay first must be developed to measure its distribution across the bilayer at a specific moment in time. The following criteria can be applied to judge the usefulness of a particular approach: (1) The procedure must recognize the lipid of interest on a membrane surface, (2) The procedure must discriminate the lipids in the one leaflet from those in the opposite leaflet of the bilayer, (3) The amount of the lipid under study should not change during the assay due to processes independent of the assay, such as via uptake by exocytosis and endocytosis with hydrolysis and (re)synthesis. Lipid sidedness and translocation may also be studied by using analogs of the lipids of interest, Examples are fluorescent analogs, spin-labeled analogs, analogs with shortened acyl chains, or a combination of these. Their sideness may then be monitored in time by the techniques mentioned above or by noninvasive spectroscopic methods. Generally, results are more convincing when confirmed by independent methods.

Published

2000

8. Transport of (glyco)sphingolipids in and between cellular membranes; multidrug transporters and lateral domains

Author

R. J. Raggers, Nanette Kälin, Hein Sprong, Daniel J. Sillence, G. van Meer, Membrane Enzymology, Universiteit Utrecht, and Dep Scheikunde

Subjects

Swine, Biophysics, Biology, Glucosylceramides, Kidney, Biochemistry, symbols.namesake, Glycolipid, Organelle, Animals, ATP Binding Cassette Transporter, Subfamily B, Member 1, Molecular Biology, Lipid raft, Cells, Cultured, Golgi membrane, Membrane Proteins, Biological Transport, Epithelial Cells, Cell Biology, Flippase, Golgi apparatus, Sphingolipid, Transmembrane protein, Cell biology, DNA-Binding Proteins, MutS Homolog 3 Protein, symbols, lipids (amino acids, peptides, and proteins), Multidrug Resistance-Associated Proteins

Abstract

Sphingolipids are highly enriched in the outer leaflet of the plasma membrane lipid bilayer. However, the first glycolipid, glucosylceramide, is synthesized in the opposite, cytosolic leaflet of the Golgi membrane. This has led us to experiments which suggest that the level of glucosylceramide in the cytosolic surface is carefully regulated both by the balance between synthesis and hydrolysis and by transport away from this surface through translocators, multidrug transporters, the same molecules that make cancer cells resistant to chemotherapy. Our data suggest a role for newly synthesized glucosylceramide not only in the formation of domains in the luminal leaflet of the Golgi but also on the cytosolic surface of this organelle.

Published

1999

9. The human multidrug resistance protein MRP1 translocates sphingolipid analogs across the plasma membrane

Author

G. van Meer, R. J. Raggers, Raymond Evers, A. van Helvoort, Membraan enzymologie, Universiteit Utrecht, and Dep Scheikunde

Subjects

Swine, Biology, Glucosylceramides, Kidney, Transfection, Substrate Specificity, symbols.namesake, Lipid translocation, Animals, Humans, Lipid Transport, Cells, Cultured, Epithelial polarity, Oxadiazoles, Sphingolipids, Cell Membrane, technology, industry, and agriculture, Kidney metabolism, Phospholipid Ethers, Lipid metabolism, Cell Biology, Basolateral plasma membrane, Golgi apparatus, Lipid Metabolism, Golgi lumen, Cell biology, DNA-Binding Proteins, MutS Homolog 3 Protein, symbols, Phosphatidylcholines, lipids (amino acids, peptides, and proteins), Multidrug Resistance-Associated Proteins

Abstract

Recently, we have provided evidence that the ABC-transporter MDR1 P-glycoprotein translocates analogs of various lipid classes across the apical plasma membrane of polarized LLC-PK1 cells transfected with MDR1 cDNA. Here, we show that expression of the basolateral ABC-transporter MRP1 (the multidrug resistance protein) induced lipid transport to the exoplasmic leaflet of the basolateral plasma membrane of LLC-PK1 cells at 15 degreesC. C6-NBD-glucosylceramide synthesized on the cytosolic side of the Golgi complex, but not C6-NBD-sphingomyelin synthesized in the Golgi lumen, became accessible to depletion by BSA in the basal culture medium. This suggests the absence of vesicular traffic and direct translocation of C6-NBD-glucosylceramide by MRP1 across the basolateral membrane. In line with this, transport of the lipid to the exoplasmic leaflet depended on the intracellular glutathione concentration and was inhibited by the MRP1-inhibitors sulfinpyrazone and indomethacin, but not by the MDR1 P-glycoprotein inhibitor PSC 833. In contrast to the broad substrate specificity of the MDR1 P-glycoprotein, MRP1 selectively transported C6-NBD-glucosylceramide and C6-NBD-sphingomyelin, the latter only when it was released from the Golgi lumen by brefeldin A. This shows the specific nature of the lipid translocation. We conclude that the transport activity of MDR1 P-glycoprotein and MRP1 must be taken into account in studies on the transport of lipids to the cell surface.

Published

1999

10. Lipid Translocation from the Cytosolic Leaflet of the Plasma Membrane to the Cell Surface by MultidrugTransporters

Author

R. J. Raggers, Gerrit van Meer, Ardy van Helvoort, and Hein Sprong

Subjects

chemistry.chemical_compound, Ceramide, Sphingosine, Chemistry, Membrane lipids, Lipid translocation, Membrane fluidity, Biophysics, lipids (amino acids, peptides, and proteins), Flippase, Sphingomyelin, Diacylglycerol kinase

Abstract

Many molecules that are exposed on the outside of the cell are involved in recognition and signaling events. This is true for receptor proteins but also for various classes of membrane lipids like the phospholipid phosphatidylserine and various glycosphingolipids. To obtain a better understanding of the function of lipids in these processes we and others have studied the general mechanisms by which lipid molecules reach the cell surface, i. e. the outer leaflet of the plasma membrane. Based on the pioneering work by Pagano and colleagues (Pagano et al., 1983; Lipsky and Pagano, 1985) we have extensively used short-chain analogs of membrane lipids. More specifically, we have added to the cells a ceramide or a diacylglycerol with a C6-NBD-fluorescent fatty acyl chain at the C2 position of the sphingosine and at the sn2 position of the diacylglycerol (Figure 1). The general idea is that these precursors will be converted to (short-chain) membrane lipids in the cell and will be transported to the plasma membrane. Because of the short-acyl chain these products will display a higher off-rate from membranes than the regular membrane lipids. Conveniently, as an assay for their appearance in the outer leaflet of the plasma membrane, they can be extracted from that surface by albumin in the bathing medium. Obviously, we hoped that the short-chain analogs would follow the same transport pathways as their natural counterparts. However, it has been clear from the start that any finding obtained by the use of short-chain lipids must finally be confirmed for the natural lipids, which generally possess two long acyl chains.

Published

1998