IDENTIFICATION OF A PUTATIVE P-TYPE ATPase INVOLVED IN ZINC AND CADMIUM RESISTANCE IN Enterobacter sp. YSU

Ngendahimana, Valentine M.

28 September 2012

No description available.

P-type ATPase

Metal resistance

Enterobactoer sp. YSU

Caracterização e expressão de dois genes codificando ATPases do tipo P em Blastocladiella emersonii / Characterization and expression of two genes encoding P-type ATPases in Blastocladiella emersonii

Luciano Gomes Fietto

23 March 2001

A TPases do tipo P são proteínas integrais de membrana que usam a energia química contida na molécula de ATP para o transporte de cátions através de membranas. O nosso trabalho apresenta a clonagem e o sequenciamento de um gene (BePAT2) e a caracterização da expressão de dois genes (BePAT1 e BePAT2) codificando isoformas de uma ATPase do tipo P no fungo aquático Blastocladiella emersonii. As proteínas codificadas por estes genes, surpreendentemente se mostraram mais similares às Na+/K+ e H+/K+-ATPases de eucariotos superiores do que a outras ATPases de fungos. Experimentos de \"Northern blot\", imunoprecipitação e \"Western blot\" demonstraram que as ATPases (BePAT1 e BePAT2) são diferencialmente expressas durante o desenvolvimento de B. emersonii. Os resultados obtidos mostraram que o aumento da transcrição dos genes refletiu em um aumento da síntese e do acúmulo das ATPases, sugerindo um controle pré-traducional da expressão de BePAT1/2. Estudos de formação de fosfoenzima na presença de diferentes íons e inibidores, utilizando as enzimas imunopurificadas, sugerem que as proteínas codificadas por estes genes tenham uma atividade semelhante às Na+/K+-ATPases. Os nossos resultados de expressão e atividade mostram pela primeira vez, evidências da funcionalidade de genes codificando uma proteína similar às Na+/K+-ATPases em um eucarioto inferior. / P- type A TPases are integral membrane proteins which use the energy stored in the A TP molecule to drive the transport of cations through biological membranes. In this work we report the cloning and sequencing of the BePAT2 gene and the characterization and expression of two genes (BePAT1 and BePAT2) encoding isoforms of a P-Type ATPase in the aquatic fungus Blastocladiella emersonii. Surprisingly the putative BePAT1 and BePAT2 proteins are more similar to Na+/K+and H+/K+-ATPases from animal cells than to other P-type ATPases from fungi. Northern blot, immunoprecipitation and Western blot experiments demonstrated that these ATPases (BePAT1 and BePAT2) are developmentally regulated in B. emersonii. The results showed that the increase in the BePAT1/2 transcription reflects in an increase in the synthesis and accumulation of the proteins, suggesting a transcriptional control of the BePAT1/2 expression. Studies of phosphoenzyme formation using the immunopurified enzymes in the presence of different ions and inhibitors suggested a Na/K-ATPase like activity. Our results demonstrate for the first time biochemical evidences of functionality of genes encoding a Na+ /K+-ATPase like protein in an eucaryotic microorganism.

ATPase tipo P

Biologia molecular

Blastocladiella

Microbiologia

Microrganismos

Blastocladiella

Microbiology

Microorganisms

Molecular biology

P-type ATPase

Caracterização e expressão de dois genes codificando ATPases do tipo P em Blastocladiella emersonii / Characterization and expression of two genes encoding P-type ATPases in Blastocladiella emersonii

Fietto, Luciano Gomes

23 March 2001

A TPases do tipo P são proteínas integrais de membrana que usam a energia química contida na molécula de ATP para o transporte de cátions através de membranas. O nosso trabalho apresenta a clonagem e o sequenciamento de um gene (BePAT2) e a caracterização da expressão de dois genes (BePAT1 e BePAT2) codificando isoformas de uma ATPase do tipo P no fungo aquático Blastocladiella emersonii. As proteínas codificadas por estes genes, surpreendentemente se mostraram mais similares às Na+/K+ e H+/K+-ATPases de eucariotos superiores do que a outras ATPases de fungos. Experimentos de \"Northern blot\", imunoprecipitação e \"Western blot\" demonstraram que as ATPases (BePAT1 e BePAT2) são diferencialmente expressas durante o desenvolvimento de B. emersonii. Os resultados obtidos mostraram que o aumento da transcrição dos genes refletiu em um aumento da síntese e do acúmulo das ATPases, sugerindo um controle pré-traducional da expressão de BePAT1/2. Estudos de formação de fosfoenzima na presença de diferentes íons e inibidores, utilizando as enzimas imunopurificadas, sugerem que as proteínas codificadas por estes genes tenham uma atividade semelhante às Na+/K+-ATPases. Os nossos resultados de expressão e atividade mostram pela primeira vez, evidências da funcionalidade de genes codificando uma proteína similar às Na+/K+-ATPases em um eucarioto inferior. / P- type A TPases are integral membrane proteins which use the energy stored in the A TP molecule to drive the transport of cations through biological membranes. In this work we report the cloning and sequencing of the BePAT2 gene and the characterization and expression of two genes (BePAT1 and BePAT2) encoding isoforms of a P-Type ATPase in the aquatic fungus Blastocladiella emersonii. Surprisingly the putative BePAT1 and BePAT2 proteins are more similar to Na+/K+and H+/K+-ATPases from animal cells than to other P-type ATPases from fungi. Northern blot, immunoprecipitation and Western blot experiments demonstrated that these ATPases (BePAT1 and BePAT2) are developmentally regulated in B. emersonii. The results showed that the increase in the BePAT1/2 transcription reflects in an increase in the synthesis and accumulation of the proteins, suggesting a transcriptional control of the BePAT1/2 expression. Studies of phosphoenzyme formation using the immunopurified enzymes in the presence of different ions and inhibitors suggested a Na/K-ATPase like activity. Our results demonstrate for the first time biochemical evidences of functionality of genes encoding a Na+ /K+-ATPase like protein in an eucaryotic microorganism.

ATPase tipo P

Biologia molecular

Blastocladiella

Blastocladiella

Microbiologia

Microbiology

Microorganisms

Microrganismos

Molecular biology

P-type ATPase

Temporal and Steric Analysis of Ionic Permeation and Binding in Na+,K+-ATPase via Molecular Dynamic Simulations

Fonseca, James E.

18 July 2008

No description available.

Bioinformatics

Biophysics

Electrical Engineering

Na+,K+-ATPase

homology modeling

molecular dynamics

P-type ATPase

Cloning and characterisation of the HMA3 gene and its promoter from Arabidopsis halleri (L.) O'Kane and Al'Shehbaz and Arabidopsis thaliana (L.) Heynhold

Hoffmann, Toni

January 2007

Being living systems unable to adjust their location to changing environmental conditions, plants display homeostatic networks that have evolved to maintain transition metal levels in a very narrow concentration range in order to avoid either deficiency or toxicity. Hence, plants possess a broad repertoire of mechanisms for the cellular uptake, compartmentation and efflux, as well as for the chelation of transition metal ions. A small number of plants are hypertolerant to one or a few specific transition metals. Some metal tolerant plants are also able to hyperaccumulate metal ions. The Brassicaceae family member Arabidopis halleri ssp. halleri (L.) O´KANE and AL´SHEHBAZ is a hyperaccumulator of zinc (Zn), and it is closely related to the non-hypertolerant and non-hyperaccumulating model plant Arabidopsis thaliana (L.) HEYNHOLD. The close relationship renders A. halleri a promising emerging model plant for the comparative investigation of the molecular mechanisms behind hypertolerance and hyperaccumulation. Among several potential candidate genes that are probably involved in mediating the zinc-hypertolerant and zinc-hyperaccumulating trait is AhHMA3. The AhHMA3 gene is highly similar to AtHMA3 (AGI number: At4g30120) in A. thaliana, and its encoded protein belongs to the P-type IB ATPase family of integral membrane transporter proteins that transport transition metals. In contrast to the low AtHMA3 transcript levels in A. thaliana, the gene was found to be constitutively highly expressed across different Zn treatments in A. halleri, especially in shoots. In this study, the cloning and characterisation of the HMA3 gene and its promoter from Arabidopsis halleri (L.) O´KANE and AL´SHEHBAZ and Arabidopsis thaliana (L.) HEYNHOLD is described. Heterologously expressed AhHMA3 mediated enhanced tolerance to Zn and to a much lesser degree to cadmium (Cd) but not to cobalt (Co) in metal-sensitive mutant strains of budding yeast. It is demonstrated that the genome of A. halleri contains at least four copies of AhHMA3, AhHMA3-1 to AhHMA3-4. A copy-specific real-time RT-PCR indicated that an AhHMA3-1 related gene copy is the source of the constitutively high transcript level in A. halleri and not a gene copy similar to AhHMA3-2 or AhHMA3-4. In accordance with the enhanced AtHMA3mRNA transcript level in A. thaliana roots, an AtHMA3 promoter-GUS gene construct mediated GUS activity predominantly in the vascular tissues of roots and not in shoots. However, the observed AhHMA3-1 and AhHMA3-2 promoter-mediated GUS activity in A. thaliana or A. halleri plants did not reflect the constitutively high expression of AhHMA3 in shoots of A. halleri. It is suggested that other factors e. g. characteristic sequence inserts within the first intron of AhHMA3-1 might enable a constitutively high expression. Moreover, the unknown promoter of the AhHMA3-3 gene copy could be the source of the constitutively high AhHMA3 transcript levels in A. halleri. In that case, the AhHMA3-3 sequence is predicted to be highly homologous to AhHMA3-1. The lack of solid localisation data for the AhHMA3 protein prevents a clear functional assignment. The provided data suggest several possible functions of the AhHMA3 protein: Like AtHMA2 and AtHMA4 it might be localised to the plasma membrane and could contribute to the efficient translocation of Zn from root to shoot and/or to the cell-to-cell distribution of Zn in the shoot. If localised to the vacuolar membrane, then a role in maintaining a low cytoplasmic zinc concentration by vacuolar zinc sequestration is possible. In addition, AhHMA3 might be involved in the delivery of zinc ions to trichomes and mesophyll leaf cells that are major zinc storage sites in A. halleri. / Pflanzen sind lebende Systeme, die nicht in der Lage sind ihren Standort sich ändernden Umweltbedingungen anzupassen. Infolgedessen weisen Pflanzen homöostatischeNetzwerke auf, welche die Mengen an intrazellulären Übergangsmetallen in einem sehr engen Konzentrationsbereich kontrollieren um somit Vergiftungs- oder Mangelerscheinungen zu vermeiden. Eine kleine Anzahl von Pflanzen ist hypertolerant gegenüber einem oder mehreren Übergangsmetallen. Einige wenige dieser metalltoleranten Pflanzen sind fähig Übergangsmetalle in beträchtlichen Mengen zu speichern, sprich zu hyperakkumulieren, ohne Vergiftungserscheinungen zu zeigen. Die Haller’sche Schaumkresse (Arabidopis halleri ssp. halleri (L.) O´KANE und AL´SHEHBAZ) aus der Familie der Kreuzblütler (Brassicaceae) ist ein solcher Hyperakkumulator für Zink (Zn). Sie ist nah verwandt mit der Modellpflanze Ackerschmalwand (Arabidopsis thaliana (L.) HEYNHOLD), die jedoch nicht-hypertolerant und nicht-hyperakkumulierend für Übergangsmetalle ist. Diese nahe Verwandtschaft erlaubt vergleichende Studien der molekularen Mechanismen, die Hypertoleranz und Hyperakkumulation zu Grunde liegen. Zu der Gruppe von Kandidatengenen, die möglicherweise von Bedeutung für die Zink-hypertoleranten und -hyperakkumulierenden Eigenschaften von A. halleri sind, gehört AhHMA3, ein Gen mit großer Ähnlichkeit zu AtHMA3 (AGI Nummer: At4g30120) aus A. thaliana. Es kodiert ein Protein aus der Familie transmembraner Übergangsmetall-Transportproteine, den P-typ IB ATPasen. Im Gegensatz zu den niedrigen AtHMA3 Transkriptmengen in A. thaliana wird das AhHMA3 Gen in A. halleri in Gegenwart verschiedener Zn Konzentrationen konstitutiv hoch exprimiert, insbesondere im Spross der Pflanze. Diese Arbeit beschreibt die Klonierung und Charakterisierung des HMA3 Gens und seines Promoters aus A. halleri und A. thaliana. Es wurde gezeigt, dass heterolog exprimiertes AhHMA3 Protein in metallsensitiven Hefestämmen eine erhöhte Toleranz gegenüber Zink und zu einem geringen Grad gegenüber Kadmium (Cd) jedoch nicht gegenüber Kobalt (Co) vermittelt.Weiterhin wurden im Genom von A. halleri mindestens vier AhHMA3 Genkopien, AhHMA3-1 bis AhHMA3-4, nachgewiesen. Eine Genkopie-spezifische Echtzeit-RT-PCR (real-time RT-PCR) deutete darauf hin, dass eine zu AhHMA3-1 und nicht zu AhHMA3-2 oder AhHMA3-4 ähnliche Genkopie die Quelle der konstitutiv hohen Transkriptmengen in A. halleri ist. In Übereinstimmung mit erhöhten mRNS Transkriptmengen inWurzeln von A. thaliana, vermittelte ein AtHMA3 Promoter-GUS (ß-Glucuronidase) Genkonstrukt GUS-Aktivität hauptsächlich in den Leitgeweben der Wurzeln jedoch nicht des Sprosses. Die vermittelte GUS-Aktivität durch Promoterfragmente von AhHMA3-1 und AhHMA3-2 in A. thaliana oder A. halleri Pflanzen spiegelte jedoch nicht die konstitutiv hohe AhHMA3 Expression im Spross von A. halleri wieder. Es wird vermutet, dass andere Faktoren die konstitutiv hohe Expression ermöglichen wie zum Beispiel die gefundenen kopiespezifischen Sequenzinsertionen innerhalb des ersten AhHMA3-1 Introns. Weiterhin ist es denkbar, dass der unbekannte Promoter der AhHMA3-3 Genkopie die Quelle der konstitutiv hohen AhHMA3 Transkriptmengen ist. In diesem Fall wird eine sehr hohe Ähnlichkeit zwischen den Sequenzen von AhHMA3-3 und der AhHMA3-1 vorhergesagt. Es konnten keine deutlichen Ergebnisse zur intrazellulären Lokalisierung gemacht werden, die eine exakte Einordnung der Funktion des AhHMA3 Proteins erlauben würden. Die bisher ermittelten Ergebnisse schlagen jedoch mehrere mögliche Funktionen für AhHMA3 vor: Ähnlich den AhHMA3 homologen Proteinen, AtHMA2 und AtHMA4, könnte AhHMA3 in der Plasmamembran der Zelle sitzen und dort zur effizienten Translokation von Zink aus der Wurzel in den Spross und/oder zur Zell-zu-Zell Verteilung von Zn im Spross beitragen. Falls AhHMA3 in der Membran der Vakuole sitzt, könnte es eine Rolle bei der Aufrechterhaltung niedriger zytoplasmatischer Zinkkonzentrationen durch vakuoläre Zinksequestrierung spielen. Zusätzlich ist es denkbar, dass AhHMA3 an der Abgabe von Zinkionen an Trichome und Blattmesophyllzellen beteiligt ist, die die Haupteinlagerungsorte für Zink in A. halleri darstellen.

P-Typ ATPase

Übergangsmetalle

Hyperakkumulation

Zink

HMA

p-type ATPase

transition metals

hyperaccumulation

zinc

HMA

Life sciences

Monte Carlo Simulations of Oligomerized Na+,K+-ATPase / Monte Carlo simulering av oligomeriserat Na+,K+-ATPas

Jönsson, Jakob

January 2022

Na+,K+-ATPase (NKA) is a membrane protein which assists in maintaining the electrochemical potential across the cell membrane. It has been suggested that the oligomerization of NKA may play a role in intracellular regulation of NKA activity. Monte Carlo simulations of NKA on a picket-fence membrane model were performed to examine if clustering has an effect on NKA efficiency. The results show that for a simple model of NKA interaction, oligomerization may drastically reduce the efficiency as measured in ATP turnover rate. Introducing a rate limit shows a clear separation between monomers and higher levels of oligomerization. / Na+,K+-ATPase (NKA) is a membrane protein which assists in maintaining the electrochemical potential across the cell membrane. It has been suggested that the oligomerization of NKA may play a role in intracellular regulation of NKA activity. Monte Carlo simulations of NKA on a picket-fence membrane model were performed to examine if clustering has an effect on NKA efficiency. The results show that for a simple model of NKA interaction, oligomerization may drastically reduce the efficiency as measured in ATP turnover rate. Introducing a rate limit shows a clear separation between monomers and higher levels of oligomerization.

biophysics

p-type ATPase

enzyme activity

simulation

biofysi

p-typ ATPas

enzym aktivitet

simulering

Physical Sciences

Fysik

The plasma membrane lipid asymmetry of Leishmania donovani and its relevance for phagocytosis

Weingärtner, Adrien

21 May 2012

In großen Teilen der Welt verursachen intrazelluläre Parasiten der Spezies Leishmania schwerwiegende Infektionen beim Menschen. Die Exposition eines Phospholipids (Phosphatidylserin, PS) steht unter Verdacht Fresszellen zur Aufnahme der Parasiten zu stimulieren. Bisher ist die Regulation der Phospholipidverteilung in der Plasmamembran dieser Parasiten kaum erforscht. In der vorliegenden Arbeit wurde ein lipidtransportierender Proteinkomplex identifiziert, der einen wesentlichen Beitrag zur asymmetrischen Lipidverteilung in der Plasmamembran von Leishmania donovani leistet. Die Zerstörung des Komplexes führte zum Verlust des einwärts gerichteten Lipidtransports und zur Anreicherung von Phosphatidylethanolamin (PE) auf der Zelloberfläche des Parasiten. Diese veränderte Lipidasymmetrie hatte jedoch keinen Einfluss auf die Phagozytose durch Makrophagen. Darüber hinaus brachte die Untersuchung des Insektenstadiums (Promastigote) verschiedener Leishmania Spezies zu Tage, dass die Menge an PS unterhalb des Detektionslimits modernster Nachweisverfahren liegt. Des Weiteren konnte gezeigt werden, dass der Parasit über einen Scramblase-Mechanismus verfügt, der durch intrazelluläres Kalzium stimulierbar ist. Die Scramblase-Aktivität ist, im Gegensatz zu dem zuvor beschriebenen einwärts gerichteten Lipidtransport, energieunabhängig und ermöglicht die bidirektionale Translokation von fluoreszenzmarkiertem Phosphatidylcholin (PC), PE, PS und Sphingomyelin (SM). Dementsprechend konnte nach Kalziumstimulierung endogenes PE auch in der äußeren Lipidschicht der Plasmamembran detektiert werden, wobei deren Barrierefunktion nicht beeinträchtigt wurde. Diese Ergebnisse geben neue Einblicke in die dynamische Regulation der Lipidverteilung über die Plasmamembran des Parasiten und verdeutlichen, dass die Exposition von PS und PE nicht essentiell für das Eindringen der Leishmanien in die Wirtszellen ist. / The protozoan parasite Leishmania causes severe infections in humans throughout the world. Following the transmission via sand flies to its mammalian host the extracellular parasite has to gain entry into phagocytic cells to initiate a successful infection. Specific surface exposed phospholipids have been implicated in Leishmania macrophage-interaction, but the mecha-nisms controlling and regulating the plasma membrane lipid distribution remains to be eluci-dated. In the present work a lipid transporting protein complex was identified in Leishmania dono-vani which plays an essential role in maintaining an asymmetric lipid distribution across the plasma membrane. Loss of the protein complex abolishes the inward-directed lipid transport and thus e.g. to an increased cell surface exposure of phosphatidylethanolamine (PE). In spite of this altered lipid asymmetry the uptake by macrophages is unaffected. Moreover, Leishma-nia promastigotes of different species lack detectable amounts of phosphatidylserine (PS) although being infective. Furthermore, a scramblase activity following a cytosolic calcium signal was demonstrated. This scramblase mechanism facilitated, in contrast to the previous described inward directed lipid transport, the bidirectional movement of fluorescent lipid analogues of PC, PE, PS and SM in an energy-independent manner. In accordance with these findings endogenous PE was exposed to the outer plasma membrane leaflet following the Ca2+-signal, while the plasma membrane itself remained intact. These results provide novel insight into the dynamic regulation of the transbilayer lipid distri-bution across the parasite plasma membrane and reveal that exposure of PS and PE is not cru-cial for invasion of the host cell by Leishmania donovani promastigotes.

Leishmania

Lipidasymmetrie

Typ 4 P-Typ ATPase

Scrambling

Phosphatidylserin

phosphatidylserine

Leishmania

lipid asymmetry

type 4 P-type-ATPase

scrambling

570 Biowissenschaften, Biologie

32 Biologie

XD 9300

ddc:570

Structure and functional dynamics of the KdpFABC P-type ATPase from Escherichia coli

Heitkamp, Thomas

17 April 2009

The KdpFABC complex from E. coli functions as a high affinity K uptake system and belongs to the superfamily of P-type ATPases. So far, no information is available about the orientation of the subunits within the complex as well as its oligomeric state. By chemical crosslinking, gel filtration, electron transmission microscopy and single particle FRET analysis this study shows that the KdpFABC complex occurs as a homodimer with a dissociation constant between 30 to 50 nM. Furthermore, by means of single particle analysis of transmission electron micrographs, the solution structure of the complex at 1.9 nm resolution could be solved, thus providing the first structural analysis resolving all subunits of the holoenzyme. Based on crystal structures, it is generally assumed that P-type ATPases undergo large domain movements during catalysis. However, these conformational changes have never been shown directly. By use of single molecule FRET with alternating laser excitation, distance changes could be measured directly within KdpB during ATP hydrolysis. With this technique, distances and dwell times were determined for three conformational states in the working enzyme as well as in the orthovanadate- and the OCS-inhibited state.

KdpFABC

P-type ATPase

potassium transport

single particle analysis

electron microscopy

ALEX-FRET

35.70 - Biochemie: Allgemeines

42.30 - Mikrobiologie

32 - Biologie

ddc:570

Novel Intrinsic and Extrinsic Approaches to Selectively Regulate Glycosphingolipid Metabolism

Kamani, Mustafa

08 August 2013

Glycosphingolipid (GSL) metabolism is a complex process involving proteins and enzymes at distinct locations within the cell. Mammalian GSLs are typically based on glucose or galactose, forming glucosylceramide (GlcCer) and galactosylceramide (GalCer). Most GSLs are derived from GlcCer, which is synthesized on the cytosolic leaflet of the Golgi, while all subsequent GSLs are synthesized on the lumenal side. We have utilized both pharamacological and genetic manipulation approaches to selectively regulate GSL metabolism and better understand its mechanistic details. We have developed analogues of GlcCer and GalCer by substituting the fatty acid moiety with an adamanatane frame. The resulting adamantylGSLs are more water-soluble than their natural counterparts. These analogues selectively interfere with GSL metabolism at particular points within the metabolic pathway. At 40 µM, adaGlcCer prevents synthesis of all GSLs downstream of GlcCer, while also elevating GlcCer levels, by inhibiting lactosylceramide (LacCer) synthase and glucocerebrosidase, respectively. AdaGalCer specifically reduces synthesis of globotriaosylceramide (Gb3) and downstream globo-series GSLs. AdaGalCer also increases Gaucher disease N370S glucocerebrosidase expression, lysosomal localization and activity. AdaGSLs, therefore, have potential as novel therapeutic agents in diseases characterized by GSL anomalies and as tools to study the effects of GSL modulation. Two predominant theories have been developed to explain how GlcCer accesses the Golgi lumen: one involving direct translocation from the cytosolic-to-lumenal leaflet of the Golgi by the ABC transporter P-glycoprotein (P-gp, ABCB1, MDR1), and the other involving retrograde transport of GlcCer by FAPP2 to the ER, followed by entry into the vesicular transport system for Golgi lumenal access. To examine the in vivo involvement of P-gp in GSL metabolism, we generated a knockout model by crossbreeding the Fabry disease mouse with the P-gp knockout mouse. HPLC analyses of tissue Gb3 levels revealed a tissue-specific reduction in MDR1/Fabry mice. TLC analyses, however, did not show such reduction. In addition, we performed a gene knockdown study using siRNA against P-gp and FAPP2. Results show these siRNA to have distinct effects on GSL levels that are cell-type specific. These results give rise to the prospect of unique therapeutic approaches by targeting P-gp or FAPP2 for synthesis inhibition of particular GSL pathways.

Sphingolipids

Metabolism

Lysosomal storage disorders

adamantane

Glucosylceramide

Lactosylceramide

P-glycoprotein

MDR1

Gaucher disease

Fabry disease

siRNA

Gb2 galabiosylceramide

Glycolipids

Inhibitors

Knockout mouse

Crossbreeding

Glucosylceramide synthase

Lactosylceramide synthase

Ganglioside

Globo-series

Gb3 synthase

pharmacological chaperone

Glucocerebrosidase

Substrate reduction therapy

ATP8B1

Cholesterol

ABC Transporters

P-type ATPase

Flippase

FAPP2

GLTP

Glycosyltransferase

Glycolipid analogues

ERAD

ABCB1

knockdown

GM3 and EGFR

GM3 and insulin receptor

Glycolipid synthesis

Glycolipid metabolism

enzyme enhancement therapy

0487

0307

0491

0379

0306

Novel Intrinsic and Extrinsic Approaches to Selectively Regulate Glycosphingolipid Metabolism

Kamani, Mustafa

08 August 2013

Glycosphingolipid (GSL) metabolism is a complex process involving proteins and enzymes at distinct locations within the cell. Mammalian GSLs are typically based on glucose or galactose, forming glucosylceramide (GlcCer) and galactosylceramide (GalCer). Most GSLs are derived from GlcCer, which is synthesized on the cytosolic leaflet of the Golgi, while all subsequent GSLs are synthesized on the lumenal side. We have utilized both pharamacological and genetic manipulation approaches to selectively regulate GSL metabolism and better understand its mechanistic details. We have developed analogues of GlcCer and GalCer by substituting the fatty acid moiety with an adamanatane frame. The resulting adamantylGSLs are more water-soluble than their natural counterparts. These analogues selectively interfere with GSL metabolism at particular points within the metabolic pathway. At 40 µM, adaGlcCer prevents synthesis of all GSLs downstream of GlcCer, while also elevating GlcCer levels, by inhibiting lactosylceramide (LacCer) synthase and glucocerebrosidase, respectively. AdaGalCer specifically reduces synthesis of globotriaosylceramide (Gb3) and downstream globo-series GSLs. AdaGalCer also increases Gaucher disease N370S glucocerebrosidase expression, lysosomal localization and activity. AdaGSLs, therefore, have potential as novel therapeutic agents in diseases characterized by GSL anomalies and as tools to study the effects of GSL modulation. Two predominant theories have been developed to explain how GlcCer accesses the Golgi lumen: one involving direct translocation from the cytosolic-to-lumenal leaflet of the Golgi by the ABC transporter P-glycoprotein (P-gp, ABCB1, MDR1), and the other involving retrograde transport of GlcCer by FAPP2 to the ER, followed by entry into the vesicular transport system for Golgi lumenal access. To examine the in vivo involvement of P-gp in GSL metabolism, we generated a knockout model by crossbreeding the Fabry disease mouse with the P-gp knockout mouse. HPLC analyses of tissue Gb3 levels revealed a tissue-specific reduction in MDR1/Fabry mice. TLC analyses, however, did not show such reduction. In addition, we performed a gene knockdown study using siRNA against P-gp and FAPP2. Results show these siRNA to have distinct effects on GSL levels that are cell-type specific. These results give rise to the prospect of unique therapeutic approaches by targeting P-gp or FAPP2 for synthesis inhibition of particular GSL pathways.

Sphingolipids

Metabolism

Lysosomal storage disorders

adamantane

Glucosylceramide

Lactosylceramide

P-glycoprotein

MDR1

Gaucher disease

Fabry disease

siRNA

Gb2 galabiosylceramide

Glycolipids

Inhibitors

Knockout mouse

Crossbreeding

Glucosylceramide synthase

Lactosylceramide synthase

Ganglioside

Globo-series

Gb3 synthase

pharmacological chaperone

Glucocerebrosidase

Substrate reduction therapy

ATP8B1

Cholesterol

ABC Transporters

P-type ATPase

Flippase

FAPP2

GLTP

Glycosyltransferase

Glycolipid analogues

ERAD

ABCB1

knockdown

GM3 and EGFR

GM3 and insulin receptor

Glycolipid synthesis

Glycolipid metabolism

enzyme enhancement therapy

0487

0307

0491

0379

0306