Étude de l'attachement de l'entérotoxine STb d'Escherichia coli à son récepteur cellulaire et du mécanisme d'action suivant cet attachement au récepteur

Labrie, Vincent

January 2001

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Oligomérisation

Sulfatide

Internalisation

Caractérisation de l'activité biologique de l'entérotoxine STb d'Escherichia coli à l'aide de membranes lipidiques artificielles et de cellules en culture

Gonçalves, Carina

January 2007

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.

Entérotoxine STb

STb enterotoxin

Perméabilisation

Permeabilization

Sulfatide

Sulfatide

Mitochondrie

Mitochondria

Caractérisation de l'activité biologique de l'entérotoxine STb d'Escherichia coli à l'aide de membranes lipidiques artificielles et de cellules en culture

Gonçalves, Carina

January 2007

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

Entérotoxine STb

STb enterotoxin

Perméabilisation

Permeabilization

Sulfatide

Sulfatide

Mitochondrie

Mitochondria

AAV-Mediated Gene Delivery Corrects CNS Lysosomal Storage in Cats with Juvenile Sandhoff Disease

Rockwell, Hannah

January 2013

Thesis advisor: Thomas N. Seyfried / Sandhoff Disease (SD) is an autosomal recessive neurodegenerative disease caused by a mutation in the Hexb gene for the β-subunit of β-hexosaminidase A, resulting in the inability to catabolize ganglioside GM2 within the lysosomes. SD presents with an accumulation of GM2 and its asialo derivative GA2 primarily in the CNS. Myelin-enriched glycolipids, cerebrosides and sulfatides, are also decreased in SD corresponding with dysmyelination. At present, no treatment exists for SD. Previous studies have shown the therapeutic benefit of using adeno-associated virus (AAV) vector-mediated gene therapy in the treatment of SD in murine and feline models. In this study, CNS tissue was evaluated from SD cats (4-6 week old) treated with bilateral injections of AAVrh8 expressing feline β-hexosaminidase α and β into the thalamus and deep cerebellar nuclei (Thal/DCN) or into the thalamus combined with intracerebroventricular injections (Thal/ICV). Both groups of treated animals had previously shown improved quality of life and absence of whole-body tremors. The activity of β-hexosaminidase was significantly elevated whereas the content of GM2 and GA2 was significantly decreased in tissue samples taken from the cerebral cortex, cerebellum, thalamus, and cervical intumescence. Treatment also increased levels of myelin-enriched cerebrosides and sulfatides in the cortex and thalamus. This study demonstrates the therapeutic benefits of AAV treatment for feline SD and suggests a similar potential for human SD patients. / Thesis (MS) — Boston College, 2013. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

AAV

Cat

Cerebroside

GM2

Sandhoff Disease

Sulfatide

Étude de l'interaction de l'entérotoxine STb d'Escherichia coli avec des cellules en culture et avec le sulfatide, son récepteur

Beausoleil, Hans-Erick

January 2001

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Entérotoxine thermostable STb

Sulfatide

Modèle cellulaire

Glycolipide

Sulfatideは樹状細胞によるα-galactosylceramideの提示を阻害する

金森, 光広

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第19147号 / 生博第330号 / 新制||生||44(附属図書館) / 32098 / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 稲葉 ｶﾖ, 教授 米原 伸, 教授 杉田 昌彦 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Sulfatide

a-galactosylceramide

樹状細胞

NKT細胞

460

Structural basis for sulfatide recognition by Disabled-2

Song, Wei

12 January 2021

Disabled-2 (Dab2) is an adaptor protein that plays critical roles in various biological processes, including protein endocytosis, platelet activation and aggregation, tumor growth, and development. In platelets, Dab2 associates with membrane sulfatide at the platelet surface, modulating platelet inside-out and outside-in signaling pathways. A Dab2-derived peptide, named the sulfatide-binding peptide (SBP), is the minimal unit of Dab2 to exert its function as a negative regulator of platelet activation and aggregation. The work of this thesis refines the model of Dab2 SBP binding to sulfatide and provides structural and functional insights into the mechanism by which Dab2 SBP modulates platelet activation. Using molecular docking, lipid-protein overlay assay, nuclear magnetic resonance, and surface plasma resonance tools, this work identifies the critical residues within two major regions responsible for sulfatide interaction. First, docking a sulfatide to Dab2 SBP, a hydrophilic region, primarily mediated by Arg42, is thought to be responsible for the association with the sulfatide headgroup. We observed that Arg 42 could directly interact with sulfatide by forming hydrogen bonds with the OS atoms in the sulfatide head group. Further lipid-protein overlay assay and surface plasma resonance experiments confirmed that both the positive charge and stereochemistry of the side chain of Dab2 SBP Arg42 are required for the sulfatide binding. Moreover, Arg42 is found to be critical in the inhibition of P-selectin expression on activated platelets. The residues nearby Arg42 (i.e., Glu33, Ty38, and Lys 44) also contribute to sulfatide interaction. Second, the second polybasic motif located at the C-terminal -helix 2 is considered to interact with the acyl chain through hydrophobic interactions rather than direct binding to the charged sulfatide head group. Lysine residues in this region are suggested to exert a dual role in sulfatide association, that is, by favoring electrostatic interactions with the negatively-charged sulfatide and/or by employing their flexible hydrocarbon spacers for hydrophobic interactions with membrane lipids. Consistent with this suggestion, we found a hydrophobic patch in the wild type Dab2 SBP structure surrounded by Lys49, Lys51, and Lys53. Furthermore, the role of the second sulfatide binding motif in sulfatide binding is confirmed by mutagenesis analysis and lipid-protein overlay assays, highlighting the ability of molecular docking to accurately predict critical residues responsible for sulfatide binding. In summary, this work provides a detailed structural basis for Dab2 recognition by sulfatide through multiple biophysical methods. The corresponding biological implications in the inhibition of platelet activation are also evaluated by flow cytometry. By elucidating the underlying mechanisms of Dab2 mediating platelet activation through sulfatide binding, we provided structural and functional insights for designing a Dab2-derived peptide with altered sulfatide recognition features in platelets, which can be further employed in antiplatelet therapy. / Doctor of Philosophy / Platelets are blood cells that are fundamentally intended to help form clots to stop bleeding. They do so by being activated after getting signals from damaged blood vessels and reaching the injury site. Consequently, they form aggregates by attracting more platelets to clump on the clot. However, platelet activation induced by a tumor cell can, in turn, protect the tumor cell from immune system elimination and facilitates their growth and spread. This platelet-tumor complex formation suggests platelets as a therapeutic target for reducing tumor migration out of the bloodstream. Our study investigates the mechanism of a Disabled-2-derived peptide, named Dab2 SBP, which upon binding to a sulfatide lipid, can reduce the platelet activation extent, using molecular and cellular approaches. The results of this study may be instrumental in the generation of Dab2 SBP-derived peptides with altered sulfatide binding ability and selectivity, which may lead to a design of an antiplatelet drug that can limit the ability of tumor cells to invade other tissues.

Disabled-2

sulfatide

liposome

platelet activation

peptide-lipid interaction

Étude des voies d’internalisation de l’entérotoxine STb d’Escherichia coli dans des lignées cellulaires

Albert, Marie-Astrid

12 1900

L’entérotoxine stable à la chaleur STb est produite par les Escherichia coli entérotoxinogènes (ETEC). Son rôle dans la diarrhée post-sevrage porcine est établi. L’internalisation de STb a été observée dans des cellules épithéliales intestinales humaines et de rat. Cependant, le mécanisme d’internalisation n’est pas totalement compris, particulièrement dans le jéjunum porcin, la cible in vivo de STb. Par la cytométrie en flux, nous avons examiné l’internalisation de STb couplée à un marqueur fluorescent dans les cellules épithéliales intestinales porcines IPEC-J2 et les fibroblastes murins NIH3T3. Nos résultats révèlent que l’internalisation de STb est températureindépendante dans les IPEC-J2 tandis qu’elle est température-dépendante dans les NIH3T3, où la réorganisation de l’actine est aussi nécessaire. Toutefois, les niveaux de sulfatide, le récepteur de STb, sont semblables à la surface des deux lignées. Le sulfatide est internalisé à 37°C de façon similaire entre les deux types cellulaires. La rupture des lipid rafts, les microdomaines membranaires contenant le sulfatide, par la méthyl-βcyclodextrine ou la génistéine, n’affecte pas l’internalisation de STb dans les deux lignées. Notre étude indique que le mécanisme d’internalisation de STb est dépendant du type cellulaire. L’activité de la cellule hôte peut être requise ou non. Le récepteur de STb, le sulfatide, n’est pas directement impliqué dans ces mécanismes. L’internalisation activité cellulaire-dépendante suggère une endocytose, nécessitant la réorganisation de l’actine mais pas les lipid rafts. L’internalisation de STb est donc un processus complexe dépendant du type cellulaire, qu’il apparait plus relevant d’étudier dans des modèles cellulaires représentatifs des conditions in vivo. / Heat-stable enterotoxin b (STb) is one of the toxins produced by enterotoxigenic Escherichia coli (ETEC) and its role in swine post-weaning diarrhea is well established. Internalization of STb in intestinal human and rat epithelial cells has been shown by previous studies. However, the uptake mechanism is still not fully understood, especially in porcine jejunum epithelium, the in vivo STb target. Using flow cytometry, we studied internalization of fluorescently-labelled STb in porcine epithelial intestinal IPEC-J2 and murine fibroblast NIH3T3 cell lines. Our results revealed that STb is internalized in both cell lines. Toxin uptake is not dependent on the temperature in IPEC-J2 cells, whereas it is in NIH3T3 fibroblasts. Actin reorganization is only required for STb internalization in NIH3T3 cells. However, membrane sulfatide, the toxin receptor, is similarly present in both cell lines and similarly internalized with time at 37°C. Disruption of lipid rafts, known to contain sulfatide, with inhibitors (methyl-βcyclodextrin or genistein), did not affect toxin uptake in both cell lines. Altogether, these data indicate that STb internalization mechanisms are cell-type dependent. Moreover, uptake can depend on host cell activity or not. Sulfatide, the toxin receptor, is not directly involved in these mechanisms. Uptake independent on cell activity occurs in porcine intestinal epithelium. The cell activity-dependent uptake suggests an endocytosis, which requires actin rearrangement and is not mediated by lipid rafts. STb internalization is therefore a complex process varying upon cell type, which should preferentially be studied in cellular models representative of in vivo conditions, such as porcine cell lines.

Escherichia coli

Entérotoxine STb

Internalisation

Type cellulaire

Sulfatide

Lipid rafts

Escherichia coli

STb enterotoxin

Internalization

Cell type

Sulfatide

Lipid rafts

Étude des voies d’internalisation de l’entérotoxine STb d’Escherichia coli dans des lignées cellulaires

Albert, Marie-Astrid

12 1900

L’entérotoxine stable à la chaleur STb est produite par les Escherichia coli entérotoxinogènes (ETEC). Son rôle dans la diarrhée post-sevrage porcine est établi. L’internalisation de STb a été observée dans des cellules épithéliales intestinales humaines et de rat. Cependant, le mécanisme d’internalisation n’est pas totalement compris, particulièrement dans le jéjunum porcin, la cible in vivo de STb. Par la cytométrie en flux, nous avons examiné l’internalisation de STb couplée à un marqueur fluorescent dans les cellules épithéliales intestinales porcines IPEC-J2 et les fibroblastes murins NIH3T3. Nos résultats révèlent que l’internalisation de STb est températureindépendante dans les IPEC-J2 tandis qu’elle est température-dépendante dans les NIH3T3, où la réorganisation de l’actine est aussi nécessaire. Toutefois, les niveaux de sulfatide, le récepteur de STb, sont semblables à la surface des deux lignées. Le sulfatide est internalisé à 37°C de façon similaire entre les deux types cellulaires. La rupture des lipid rafts, les microdomaines membranaires contenant le sulfatide, par la méthyl-βcyclodextrine ou la génistéine, n’affecte pas l’internalisation de STb dans les deux lignées. Notre étude indique que le mécanisme d’internalisation de STb est dépendant du type cellulaire. L’activité de la cellule hôte peut être requise ou non. Le récepteur de STb, le sulfatide, n’est pas directement impliqué dans ces mécanismes. L’internalisation activité cellulaire-dépendante suggère une endocytose, nécessitant la réorganisation de l’actine mais pas les lipid rafts. L’internalisation de STb est donc un processus complexe dépendant du type cellulaire, qu’il apparait plus relevant d’étudier dans des modèles cellulaires représentatifs des conditions in vivo. / Heat-stable enterotoxin b (STb) is one of the toxins produced by enterotoxigenic Escherichia coli (ETEC) and its role in swine post-weaning diarrhea is well established. Internalization of STb in intestinal human and rat epithelial cells has been shown by previous studies. However, the uptake mechanism is still not fully understood, especially in porcine jejunum epithelium, the in vivo STb target. Using flow cytometry, we studied internalization of fluorescently-labelled STb in porcine epithelial intestinal IPEC-J2 and murine fibroblast NIH3T3 cell lines. Our results revealed that STb is internalized in both cell lines. Toxin uptake is not dependent on the temperature in IPEC-J2 cells, whereas it is in NIH3T3 fibroblasts. Actin reorganization is only required for STb internalization in NIH3T3 cells. However, membrane sulfatide, the toxin receptor, is similarly present in both cell lines and similarly internalized with time at 37°C. Disruption of lipid rafts, known to contain sulfatide, with inhibitors (methyl-βcyclodextrin or genistein), did not affect toxin uptake in both cell lines. Altogether, these data indicate that STb internalization mechanisms are cell-type dependent. Moreover, uptake can depend on host cell activity or not. Sulfatide, the toxin receptor, is not directly involved in these mechanisms. Uptake independent on cell activity occurs in porcine intestinal epithelium. The cell activity-dependent uptake suggests an endocytosis, which requires actin rearrangement and is not mediated by lipid rafts. STb internalization is therefore a complex process varying upon cell type, which should preferentially be studied in cellular models representative of in vivo conditions, such as porcine cell lines.

Escherichia coli

Entérotoxine STb

Internalisation

Type cellulaire

Sulfatide

Lipid rafts

Escherichia coli

STb enterotoxin

Internalization

Cell type

Sulfatide

Lipid rafts

Sulfatide is required for organization of the paranode in the myelinated axon in the peripheral nervous system

Kwong, Eva

28 April 2011

Myelin facilitates the timely, efficient conduction of action potentials along axons. Made by Schwann cells (SCs) in the PNS, myelin is unique in that it is composed of a high percentage of lipids, particularly galactolipids. Sulfatide, one such galactolipid, is made by cerebroside sulfotransferase (CST) and has been shown to play a role in organizing paranodal domains in myelinated axons. However less is known regarding the involvement of sulfatide in the establishment and maintenance of the node, of particular interest as it is responsible for the potentiation of action potentials along the axon. Using immunohistochemical and, to a lesser extent, electron microscopic techniques, we confirm that sulfatide is essential for organization of the paranode. Our data further shows that neuronal nodal clustering and maintenance is paranode-independent, thus not reliant on sulfatide, demonstrating that 1) distinct mechanisms exist for nodal and paranodal organization 2) distinct mechanisms for nodal stability exist in the PNS versus the CNS. Interestingly, maintenance of the SC nodal protein, gliomedin, is sulfatide-dependent, indicating that sulfatide is differentially important for nodal organization depending on the cell of origin. Finally, we observe that despite compromised molecular organization of the nodal and paranodal domains in the absence of sulfatide, the gross structure is preserved, therefore a disconnect exists between molecular and structural organization.

Myelin

sulfatide

peripheral nervous system

Anatomy

Medicine and Health Sciences

Nervous System