The effect of α-tocopherol on the membrane dipole potential

Le Nen Davey, Sterenn

January 2011

α-Tocopherol has a well known antioxidant action but is also considered likely to exert significant non-antioxidant effects in cell membranes. Due to its lipophilic nature α-tocopherol inserts into biological membranes where it influences the organisation of the component lipids and may therefore influence biophysical parameters including the membrane dipole potential. The dipole potential has been demonstrated to modulate the function of several membrane associated proteins and perturbation of this physical parameter by α-tocopherol may prove to be a significant non-antioxidant mechanism underlying several of its cellular effects. This study investigates the influence of α-tocopherol, and the non-antioxidant structural analogue α-tocopherol succinate, on the membrane dipole potential employing fluorescence spectroscopy techniques with the dipole potential sensitive probe Di-8-ANEPPS. Similar techniques are utilised with the surface potential sensitive probe FPE to investigate the interaction of the charged α-tocopherol succinate molecule with membranes. α-Tocopherol and α-tocopherol succinate are shown to decrease the dipole potential of egg-phosphatidylcholine vesicles and Jurkat T-lymphocyte cell membranes. This effect is placed in the context of the significant influence of membrane cholesterol oxidation on the dipole potential. 7-ketocholesterol, an oxidised form of cholesterol, significantly influences several cellular processes and is thought to mediate these effects, in part, through its physical effects on the cell membrane. These include altering the composition, and therefore biophysical properties, of rafts; structures which are considered to support the function of a host of membrane proteins. This study attempts to correlate the effect of 7-ketocholesterol on the dipole potential of microdomains with the influence of the oxysterol on the function of two microdomains associated receptors: P-glycoprotein and the insulin receptor, assessed by determining the extent of ligand binding using flow fluorocytometry. α-Tocopherol has been suggested to inhibit the raft-mediated effects of 7-ketocholesterol and the influence of this molecule on the effect of 7-ketocholesterol on the dipole potential are investigated as a potential mechanism for this inhibition. It is hypothesized that α-tocopherols may protect against the deleterious effects of cholesterol oxidation in cell membranes by excluding 7-ketocholesterol from specific microdomains, of which rafts are a subset, acting to preserve their dipole potential and maintain the function of the proteins they support. However, where significant cholesterol oxidation has previously occured the concurrent changes in the microdomain landscape of the membrane is suggested to prevent α-tocopherol succinate from eliciting this protective effect.

572

Particulate allergens potentiate allergic asthma in mice through sustained IgE-mediated mast cell activation.

Jin, C, Shelburne, CP, Li, G, Potts, EN, Riebe, KJ, Sempowski, GD, Foster, WM, Abraham, SN

03 1900

Allergic asthma is characterized by airway hyperresponsiveness, inflammation, and a cellular infiltrate dominated by eosinophils. Numerous epidemiological studies have related the exacerbation of allergic asthma with an increase in ambient inhalable particulate matter from air pollutants. This is because inhalable particles efficiently deliver airborne allergens deep into the airways, where they can aggravate allergic asthma symptoms. However, the cellular mechanisms by which inhalable particulate allergens (pAgs) potentiate asthmatic symptoms remain unknown, in part because most in vivo and in vitro studies exploring the pathogenesis of allergic asthma use soluble allergens (sAgs). Using a mouse model of allergic asthma, we found that, compared with their sAg counterparts, pAgs triggered markedly heightened airway hyperresponsiveness and pulmonary eosinophilia in allergen-sensitized mice. Mast cells (MCs) were implicated in this divergent response, as the differences in airway inflammatory responses provoked by the physical nature of the allergens were attenuated in MC-deficient mice. The pAgs were found to mediate MC-dependent responses by enhancing retention of pAg/IgE/FcεRI complexes within lipid raft–enriched, CD63(+) endocytic compartments, which prolonged IgE/FcεRI-initiated signaling and resulted in heightened cytokine responses. These results reveal how the physical attributes of allergens can co-opt MC endocytic circuitry and signaling responses to aggravate pathological responses of allergic asthma in mice. / Dissertation

Air Pollutants

Allergens

Animals

Antigens, CD

Antigens, CD63

Asthma

Bronchial Hyperreactivity

Disease Models, Animal

Endocytosis

Gene Expression Regulation

Hypersensitivity

Immunoglobulin E

Inflammation

Lipids

Male

Mast Cells

Membrane Microdomains

Mice

Mice, Inbred C57BL

Platelet Membrane Glycoproteins

Desestruturação de lipid rafts por ácido docosaexaenoico (DHA) induz apoptose em células epiteliais luminais da glândula mamária humana transformadas pela superexpressão de HER-2 / Lipid rafts disruption by docosahexaenoic acid (DHA) induces apoptosis in transformed human mammary luminal epithelial cells harboring HER-2 overexpression

Ravacci, Graziela Rosa

21 March 2013

A superexpressão de receptores HER-2 é anormalidade celular de grande relevância clínica no câncer de mama. Ela ocorre em aproximadamente 30% de carcinomas de mama incluindo lesões pré-neoplásicas e malignas, e está associada a prognóstico desfavorável. A hiperativação dos receptores HER-2, consequência natural de sua superexpressão, promove proliferação celular aberrante e tumorigênese. Admite-se que a ativação e envio de sinais via HER-2 possa acontecer quando estes receptores se encontram em compartimentos específicos da membrana celular, os lipid rafts. Assim, um número maior de HER-2 poderia implicar em maior quantidade de lipis rafts. Para testar essa hipótese, usamos modelo de transformação oncogênica que nos permitiu avaliar, especificamente, os efeitos da superexpressão de HER-2 e identificar a quantidade de lipid rafts. Para isso utilizamos a linhagem celular HB4a, derivada de célula epitelial luminal do tecido mamário humano normal com baixa expressão de HER-2; e a linhagem HB4aC5.2, um clone derivado da HB4a, que superexpressa receptores HER-2. Nas células HB4aC5.2, a superexpressão de HER-2 foi acompanhada pelo aumento dos lipid rafts na membrana celular, bem como, hiperativação de sinais de sobrevivência, proliferação (aumento da ativação de proteínas Akt e Erk1/2, respectivamente), e taxa de proliferação celular duas vezes mais rápida que a linhagem normal HB4a. Adicionalmente, a superexpressão de HER-2 foi associada com aumento da lipogênese celular (fenótipo lipogênico), dependente do aumento de ativação da enzima FASN e da superexpressão de DEPTOR. A FASN é responsável pela síntese de palmitato, utilizado para formação de lipid rafts. A superexpressão de DEPTOR, por modular a atividade transcricional de PPAR?, pode evitar a lipotoxicidade do excesso de palmitato. Além disso, DEPTOR, por sua capacidade em reduzir atividade do complexo mTORC1, contribui para sobrevivência celular dependente da proteína Akt. Em continuidade, consideramos, como segunda hipótese, que a desestruturação de lipid rafts poderia influenciar negativamente a ativação dos receptores HER-2. Para isso tratamos, as mesmas linhagens celulares anteriormente descritas, com ácido docosaexaenoico (DHA), um tipo de ácido graxo ômega-3. Nossos resultados mostraram que, nas células HB4aC5.2, o tratamento com DHA desestruturou os lipid rafts, inibiu a sinalização iniciada pelos receptores HER-2 ( diminuição da ativação das proteínas Akt, Erk1/2, FASN, atividade transcricional de PPAR? e expressão de DEPTOR) e reverteu o fenótipo lipogênico. Adiciona-se que essas modificações celulares e moleculares foram acompanhadas por indução significativa de morte e apoptose. As mesmas alterações não foram observadas nas células normais HB4a. Em conclusão, o presente estudo reforça a associação entre a presença de HER-2 e lipid rafts. Adicionalmente aponta que a desestruturação de lipid rafts por DHA reduz a sinalização de HER-2. Por fim, sugere que distúrbios em lipid rafts, induzidos por DHA, possam representar ferramenta útil no controle da sinalização aberrante deflagrada pelos receptores HER-2, e aponta potencial terapêutico na suplementação de DHA para quimioprevenção e tratamento do câncer de mama HER-2 positivo. / HER-2 receptor overexpression is a cellular abnormality of great clinical significance in breast cancer. It is described in approximately 30% of breast carcinomas, including preneoplasic and malignant lesions, and is associated with poor prognosis. Hyperactivation of HER-2 receptors, a natural consequence of its overexpression, promotes aberrant cell proliferation and tumorigenesis. For signal activation and transduction to occur, HER-2 must be localized in specific compartments in the cell membrane: the lipid rafts. Therefore, we hypothesize that a greater number of HER-2 receptors could indicate a greater quantity of lipid rafts. To test this, we used an oncogenic transformation model that specifically allowed assessment of the effects of HER-2 overexpression and identification of the quantity of lipid rafts: an HB4a cell line derived from normal human breast tissue luminal epithelial cells with low HER-2 expression, and an HB4aC5.2 cell line, a clone derived from HB4a that overexpresses HER-2 receptors. In the HB4aC5.2 cells, HER-2 overexpression was accompanied by an increase in lipid rafts in cell membranes as well as hyperactivation of survival signals, proliferation (increased activation of the proteins Akt and ERK1/2, respectively), and an increased rate of proliferation, compared to the normal HB4a line. In addition, HER-2 overexpression was associated with increased cellular lipogenesis (lipogenic phenotype), dependent on the increased activation of the FASN enzyme and the overexpression of DEPTOR. FASN is responsible for the synthesis of palmitate, used to synthesize lipid rafts. Overexpression of DEPTOR by modulating PPAR? transcriptional activity, may avoid lipotoxicity from excess palmitate. Moreover, DEPTOR, with its ability to reduce mTORC1 complex activity, contributes to cell survival dependent on Akt. To continue, we considered as a second hypothesis that the disruption of lipid rafts could negatively influence HER-2 receptor activation. For this, we treated the same cell lines described above with docosahexaenoic acid (DHA), a omega-3 fatty acid. Our results showed that in HB4aC5.2 cells DHA treatment disrupted the lipid rafts, inhibited signaling initiated by HER-2 receptors (reduced activation of Akt, ERK1/2, and FASN proteins, PPAR? transcriptional activity, and DEPTOR expression) and reversed the lipogenic phenotype. In addition, these cellular and molecular changes were accompanied by a significant induction of apoptosis and death. The same changes were not observed in normal HB4a cells. In conclusion, the present study reinforces the association between HER-2 presence and lipid rafts. It also indicates that the disruption of lipid rafts by DHA reduces HER-2 signaling. Finally, it suggests that DHA-induced disturbances in lipid rafts may represent a useful tool in controlling aberrant signaling triggered by HER-2 receptors, and indicate therapeutic potential in DHA supplementation for chemoprevention and treatment of HER-2 positive breast cancer.

Ácidos graxos ômega 3

Apoptose

Apoptosis

Breast neoplasias

Epidermal growth factor receptor HER-2

Fatty acids omega-3

Membrane microdomains

Microdomínios da membrana

Neoplasias da mama

Signal transduction

Transdução de sinal

Estudos sobre o envolvimento de “membrane rafts” e a ativação de quinases de células epiteliais durante a interação com paracoccidioides brasiliensis / Studies on membrane rafts involvement and kinases activation of epithelial cells during interaction with paracoccidioides brasiliensis

Maza, Paloma Korehisa [UNIFESP]

30 January 2008

Made available in DSpace on 2015-07-22T20:50:11Z (GMT). No. of bitstreams: 0 Previous issue date: 2008-01-30. Added 1 bitstream(s) on 2015-08-11T03:26:36Z : No. of bitstreams: 1 Publico-Tese%20Paloma%20Korehiza%20Maza%20versao%20final.pdf: 1568579 bytes, checksum: 8a94eab5c79046acd8162d9a949d2c36 (MD5) / Muitos patógenos são capazes de manipular a sinalização de células do hospedeiro para facilitar sua infecção. Nesta tese, demonstramos que o fungo Paracoccidioides brasiliensis promove um aumento na ativação de ERK1/2 e SFKs em células epiteliais A549 (de pulmão humano), de aproximadamente 6 e 7 vezes, respectivamente, em relação aos níveis basais. Utilizando PP2, inibidor da atividade de SFKs, e PD98059, inibidor da ativação da via ERK1/2, verificamos que a ativação de ERK1/2 é parcialmente dependente de SFKs ativadas e que provavelmente outras quinases também estão envolvidas neste evento. Além da modulação da sinalização de células do hospedeiro, diversos estudos têm demonstrado que patógenos seqüestram domínios presentes nas membranas da célula hospedeira denominados “membrane rafts”, os quais são enriquecidos em esfingolipídeos e colesterol e estão envolvidos em diversos eventos celulares, incluindo a sinalização celular. Por diferentes metodologias, como a desorganização de “membrane rafts” por drogas que extraem (metil-β- ciclodextrina, MβCD) ou que se ligam (nistatina) ao colesterol, e a localização do gangliosídeo GM1, um marcador de “membrane rafts”, utilizando a subunidade B da toxina da cólera (CTB), mostramos o envolvimento destes domínios de membranas de células epiteliais na adesão de P. brasiliensis. A partir do isolamento de membranas resistentes a detergente (DRMs) de células epiteliais após incubação com o fungo, mostramos a ativação e o deslocamento de SFKs para as frações que contêm os “membrane rafts”. Além disso, verificamos que a depleção do colesterol com MβCD inibe completamente a ativação de SFKs, corroborando a importância dos domínios de membranas para a ativação destas quinases. Os resultados apresentados nesta tese demonstram, pela primeira vez, que fungos patogênicos modulam a organização e a atividade de “membrane rafts” de células hospedeiras para o estabelecimento da infecção. / Many pathogens are able to manipulate host cell signaling in order to facilitate infection. In this thesis, we demonstrated that the fungus Paracoccidioides brasiliensis promotes an increase of ERK12 and SFK activation in A549 epithelial cells (human lung cells), by approximately 6- and 7-fold over basal levels, respectively. By using PP2, inhibitor for SFK activity, and PD98059, inhibitor for ERK1/2 activation, we verified that ERK1/2 activation is partially dependent of activated SFKs and probably other kinases are involved in this event. Besides modulation of host cell signaling, several studies have been demonstrated that pathogens hijack domains that are present in host cell membranes called membrane rafts, which are cholesterol- and sphingolipidenriched domains, that are involved in several cell events, including cell signaling. By using several approaches, such as membrane rafts disruption with cholesterolextractor (methyl-β-cyclodextrin, MβCD) or –binding (nystatin) drugs, and the localization of ganglioside GM1, a membrane raft marker, by using cholera toxin subunit B (CTB), we showed the involvement of these epithelial cell membrane domains in P. brasiliensis adhesion. By isolating detergent-resistant membrane (DRM) from epithelial cells after incubation with this fungus, we showed the activation and the dislodgment of SFKs to fractions which contain membrane rafts. Moreover, we verified that cholesteroldepletion with MβCD completely inhibits SFK activation, corroborating the importance of membrane domains in activation of these kinases.The results presented in this thesis demonstrate for the first time that pathogenic fungi may modulate the organization and activity of host cell membrane rafts for infection establishment. / TEDE / BV UNIFESP: Teses e dissertações

Microdomínios da membrana

Quinases da família src

Relações hospedeiro-parasita

Paracoccidioides

Membrane microdomains

src-family kinases

Host-parasite interactions

Paracoccidioides

Desestruturação de lipid rafts por ácido docosaexaenoico (DHA) induz apoptose em células epiteliais luminais da glândula mamária humana transformadas pela superexpressão de HER-2 / Lipid rafts disruption by docosahexaenoic acid (DHA) induces apoptosis in transformed human mammary luminal epithelial cells harboring HER-2 overexpression

Graziela Rosa Ravacci

21 March 2013

A superexpressão de receptores HER-2 é anormalidade celular de grande relevância clínica no câncer de mama. Ela ocorre em aproximadamente 30% de carcinomas de mama incluindo lesões pré-neoplásicas e malignas, e está associada a prognóstico desfavorável. A hiperativação dos receptores HER-2, consequência natural de sua superexpressão, promove proliferação celular aberrante e tumorigênese. Admite-se que a ativação e envio de sinais via HER-2 possa acontecer quando estes receptores se encontram em compartimentos específicos da membrana celular, os lipid rafts. Assim, um número maior de HER-2 poderia implicar em maior quantidade de lipis rafts. Para testar essa hipótese, usamos modelo de transformação oncogênica que nos permitiu avaliar, especificamente, os efeitos da superexpressão de HER-2 e identificar a quantidade de lipid rafts. Para isso utilizamos a linhagem celular HB4a, derivada de célula epitelial luminal do tecido mamário humano normal com baixa expressão de HER-2; e a linhagem HB4aC5.2, um clone derivado da HB4a, que superexpressa receptores HER-2. Nas células HB4aC5.2, a superexpressão de HER-2 foi acompanhada pelo aumento dos lipid rafts na membrana celular, bem como, hiperativação de sinais de sobrevivência, proliferação (aumento da ativação de proteínas Akt e Erk1/2, respectivamente), e taxa de proliferação celular duas vezes mais rápida que a linhagem normal HB4a. Adicionalmente, a superexpressão de HER-2 foi associada com aumento da lipogênese celular (fenótipo lipogênico), dependente do aumento de ativação da enzima FASN e da superexpressão de DEPTOR. A FASN é responsável pela síntese de palmitato, utilizado para formação de lipid rafts. A superexpressão de DEPTOR, por modular a atividade transcricional de PPAR?, pode evitar a lipotoxicidade do excesso de palmitato. Além disso, DEPTOR, por sua capacidade em reduzir atividade do complexo mTORC1, contribui para sobrevivência celular dependente da proteína Akt. Em continuidade, consideramos, como segunda hipótese, que a desestruturação de lipid rafts poderia influenciar negativamente a ativação dos receptores HER-2. Para isso tratamos, as mesmas linhagens celulares anteriormente descritas, com ácido docosaexaenoico (DHA), um tipo de ácido graxo ômega-3. Nossos resultados mostraram que, nas células HB4aC5.2, o tratamento com DHA desestruturou os lipid rafts, inibiu a sinalização iniciada pelos receptores HER-2 ( diminuição da ativação das proteínas Akt, Erk1/2, FASN, atividade transcricional de PPAR? e expressão de DEPTOR) e reverteu o fenótipo lipogênico. Adiciona-se que essas modificações celulares e moleculares foram acompanhadas por indução significativa de morte e apoptose. As mesmas alterações não foram observadas nas células normais HB4a. Em conclusão, o presente estudo reforça a associação entre a presença de HER-2 e lipid rafts. Adicionalmente aponta que a desestruturação de lipid rafts por DHA reduz a sinalização de HER-2. Por fim, sugere que distúrbios em lipid rafts, induzidos por DHA, possam representar ferramenta útil no controle da sinalização aberrante deflagrada pelos receptores HER-2, e aponta potencial terapêutico na suplementação de DHA para quimioprevenção e tratamento do câncer de mama HER-2 positivo. / HER-2 receptor overexpression is a cellular abnormality of great clinical significance in breast cancer. It is described in approximately 30% of breast carcinomas, including preneoplasic and malignant lesions, and is associated with poor prognosis. Hyperactivation of HER-2 receptors, a natural consequence of its overexpression, promotes aberrant cell proliferation and tumorigenesis. For signal activation and transduction to occur, HER-2 must be localized in specific compartments in the cell membrane: the lipid rafts. Therefore, we hypothesize that a greater number of HER-2 receptors could indicate a greater quantity of lipid rafts. To test this, we used an oncogenic transformation model that specifically allowed assessment of the effects of HER-2 overexpression and identification of the quantity of lipid rafts: an HB4a cell line derived from normal human breast tissue luminal epithelial cells with low HER-2 expression, and an HB4aC5.2 cell line, a clone derived from HB4a that overexpresses HER-2 receptors. In the HB4aC5.2 cells, HER-2 overexpression was accompanied by an increase in lipid rafts in cell membranes as well as hyperactivation of survival signals, proliferation (increased activation of the proteins Akt and ERK1/2, respectively), and an increased rate of proliferation, compared to the normal HB4a line. In addition, HER-2 overexpression was associated with increased cellular lipogenesis (lipogenic phenotype), dependent on the increased activation of the FASN enzyme and the overexpression of DEPTOR. FASN is responsible for the synthesis of palmitate, used to synthesize lipid rafts. Overexpression of DEPTOR by modulating PPAR? transcriptional activity, may avoid lipotoxicity from excess palmitate. Moreover, DEPTOR, with its ability to reduce mTORC1 complex activity, contributes to cell survival dependent on Akt. To continue, we considered as a second hypothesis that the disruption of lipid rafts could negatively influence HER-2 receptor activation. For this, we treated the same cell lines described above with docosahexaenoic acid (DHA), a omega-3 fatty acid. Our results showed that in HB4aC5.2 cells DHA treatment disrupted the lipid rafts, inhibited signaling initiated by HER-2 receptors (reduced activation of Akt, ERK1/2, and FASN proteins, PPAR? transcriptional activity, and DEPTOR expression) and reversed the lipogenic phenotype. In addition, these cellular and molecular changes were accompanied by a significant induction of apoptosis and death. The same changes were not observed in normal HB4a cells. In conclusion, the present study reinforces the association between HER-2 presence and lipid rafts. It also indicates that the disruption of lipid rafts by DHA reduces HER-2 signaling. Finally, it suggests that DHA-induced disturbances in lipid rafts may represent a useful tool in controlling aberrant signaling triggered by HER-2 receptors, and indicate therapeutic potential in DHA supplementation for chemoprevention and treatment of HER-2 positive breast cancer.

Ácidos graxos ômega 3

Apoptose

Microdomínios da membrana

Neoplasias da mama

Transdução de sinal

Apoptosis

Breast neoplasias

Epidermal growth factor receptor HER-2

Fatty acids omega-3

Membrane microdomains

Signal transduction