NEURAMINIDASE-1 SIALIDASE AND MATRIX METALLOPROTEINASE-9 CROSSTALK IN ALLIANCE WITH INSULIN RECEPTORS IS AN ESSENTIAL MOLECULAR SIGNALING PLATFORM FOR INSULIN-INDUCED RECEPTOR ACTIVATION

ALGHAMDI, FARAH

20 February 2013

Molecular-targeting therapeutics directed towards growth factor receptors have become promising interventions in cancer. They include the family of mammalian receptor tyrosine kinases such as epidermal growth factor, TrkA and insulin. In particular, the insulin receptor (IR) is one of the most well-known members of the RTK family of receptors playing a role in cancer. IRs are covalently-linked heterodimers of αβ subunits on the cell membrane in the absence of insulin. The IR signaling pathways are initially triggered by insulin binding to the α subunits followed by the interaction of β subunits and ATP. The parameter(s) controlling IR activation remains unknown. Here, we report a membrane receptor signaling platform initiated by insulin binding to its receptor to induce Neu1 in live HTC-IR and MiaPaCa-2 cell lines. Microscopy colocalization and co-immunoprecipitation analyses reveal that Neu1 and MMP9 form a complex with naïve and insulin-treated receptors. Tamiflu (neuraminidase inhibitor), galardin and piperazine (broad range MMP inhibitors), MMP9 specific inhibitor and anti-Neu1 antibody blocked Neu1 activity associated with insulin stimulated live cells. Moreover, Tamiflu, anti-Neu1 antibody, and MMP9 specific inhibitor blocked insulin induced insulin receptor substrate-1 phosphorylation (p-IRS1). The previous findings reveal a molecular organizational signaling platform of Neu1 and MMP-9 crosstalk in alliance with insulin receptors. It proposes that insulin binding to the receptor induces MMP9 to activate Neu1, which hydrolyzes α-2,3 sialic acid in removing steric hindrance to generate a functional receptor. The results predict a prerequisite desialylation process by activated Neu1. A complete understanding of IR activation and the role of sialic acids in the iii signaling pathways may provide a therapeutic strategy in the prevention of different diseases such as diabetes mellitus and cancer. / Thesis (Master, Microbiology & Immunology) -- Queen's University, 2013-02-20 11:27:44.861

insulin receptors

MMP-9

NEURAMINIDASE-1

Influence des peptides d'élastine dans le diabète de type 2 et la thrombose et caractérisation biochimique et fonctionnelle de la sous-unité Neuraminidase-1 du complexe récepteur de l'élastine / Role of elastin peptides in type 2 diabetes and thrombosis, and functionality and biochemical characterization of Neuraminidase-1, subunit of elastin receptor complex

Kawecki, Charlotte

16 December 2015

L’élastine est la protéine de la matrice extracellulaire (MEC) responsable des propriétés de résilience et d'élasticité des tissus élastiques. Durant le vieillissement, les protéines de la MEC vasculaire sont exposées à des réactions délétères qui altèrent leurs propriétés structurales et fonctionnelles. Une des caractéristiques principales des protéines de la MEC est leur longue demi-vie, associée à un renouvellement très lent, comme pour l'élastine. Ainsi, tout dommage survenant sur l'élastine est essentiellement irréparable. La fragmentation des fibres élastiques génère des peptides d’élastine (EDP) bioactifs capables de modifier le comportement des cellules environnantes en se liant au complexe récepteur de l’élastine (CRE), composé de trois sous-unités dont la neuraminidase-1 (Neu-1), sous-unité catalytique du CRE. Cette thèse a consisté en l'étude, chez la souris, du rôle des EDP dans le développement du diabète de type 2 et dans la thrombose, deux pathologies vasculaires liées à l'âge, et s'est également focalisée sur la sous-unité Neu-1 du CRE. Dans un premier temps, nous avons montré que les EDP favorisent le développement d’une insulinorésistance et d’un diabète de type 2. Cet effet implique l'interaction de Neu-1 avec la sous-unité β du récepteur à l'insuline qui diminue son niveau de sialylation altérant ses voies de signalisation. Dans un second temps, nous avons identifié un mécanisme d'action des EDP à deux niveaux (matriciel et plaquettaire) et mis en évidence la présence d'un CRE fonctionnel dans les plaquettes régulant la thrombose. Enfin, nous avons étudié la topologie membranaire de Neu-1 par différentes approches technologiques et identifié un domaine transmembranaire potentiel jouant un rôle important pour sa dimérisation et son activité sialidase. En conclusion, les EDP sont des acteurs clefs du remodelage vasculaire physiopathologique et des pathologies vasculaires associées et de contribuer à faire avancer nos connaissances sur l'organisation de Neu-1 à la membrane plasmique. / Elastin is the extracellular matrix (ECM) protein responsible for resilience and elasticity of tissues such as arteries. During ageing, vascular ECM proteins are subjected to deleterious reactions that alter their structural and functional properties (addition reactions, proteolysis). One of the main features of ECM proteins is their long half-life, associated with a low, or even, inexistent turnover. This is the case for elastin with an estimated half-life at 70 years. Therefore, any damage occurring on elastin will be mostly irreparable. Fragmentation of elastic fibers produces bioactive elastin-derived peptides (EDP) able to modify the behavior of surrounding cells by binding to the elastin receptor complex (ERC). This receptor is composed of three subunits, among which neuraminidase-1 (Neu-1) is the catalytic subunit. The aim of this thesis was to study, in mice, the role of EDP in the development of type 2 diabetes and in thrombosis, two age-related vascular diseases, and to focus on the Neu-1 subunit of the ERC. In a first time, we have shown that EDP promote the development of insulin resistance and type 2 diabetes. This effect involves Neu-1 interaction with the β subunit of the insulin receptor and leads to its reduced sialylation level and signaling. In a second time, we have demonstrated that EDP are regulators of thrombosis. We identified a two-level mechanism (matrix and platelet) and the presence of a functional ERC in platelets. Finally, we have studied the membrane topology of Neu-1 by different biophysical, biochemical and molecular biology approaches, and identified a potential transmembrane domain involved in the dimerization and sialidase activity of Neu-1. In conclusion, this thesis consolidates the concept that EDP are crucial actors of pathophysiological vascular remodeling and related vascular diseases, and expands our knowledge on the plasma membrane organization of Neu-1.

Peptides d'elastine

Diabète

Thrombose

Plaquettes

Neuraminidase-1

Dimérisation

Elastin peptides

Diabetes

Thrombosis

Platelets

Neuraminidase-1

Dimerization

Etude du mode de fonctionnement du complexe récepteur de l'élastine : modulation de la composition et de la dynamique de la membrane plasmique / Study of the elastin complex receptor operating mechanism : modulation of the dynamic and composition of plasma membrane.

Rusciani, Anthony

28 September 2012

L'élastine est la protéine matricielle responsable de l'élasticité des tissus retrouvée dans des tissus soumis à de fortes contraintes mécaniques tels que les poumons, les artères ou la peau. La dégradation de cette protéine lors de processus physiopathologiques produit des peptides bologiquement actifs nommés peptides d'élastine portant le motif GXXPG essentiel à leur activité. Ces peptides régulent diverses fonctions biologiques telles que le chimiotactisme, la synthèse de protéases, la prolifération. Tous ces effets dépendent de la fixation des peptides d'élastine au complexe récepteur de l'élastine. Ce complexe est composé de trois sous-unités : une protéine périphérique de 67 kDa, l'Elastin Binding Protein (EBP), et deux protéines associées à la membrane, la Protective Protein/Cathepsin A (PP/CA) et la Neuraminidase-1 (Neu-1) de 55 et 61 kDa respectivement. L'activité sialidase de Neu-1 est responsable de l'activation de ERK 1/2 après fixation des peptides d'élastine au complexe récepteur de l'élastine.Dans cette étude, nous démontrons que l'EBP et les radeaux lipidiques sont colocalisés à la membrane plasmique. Nous montrons, de plus, que la déstructuration de ces microdomaines aussi bien que leur déplétion en glycolipides bloque la signalisation du récepteur. L'utilisation d'un anticorps monoclonal bloquant dirigé contre le GM3 montre qu'il est essentiel à la signalisation. Après traitement par les peptides d'élastine, le contenu cellulaire en GM3 diminue alors que celui en lactosylcéramide augmente suggérant une conversion du GM3 en lactosylcéramide. L'utilisation de lactose ou de siRNA Neu-1 bloque cette conversion ce qui tend à démontrer que le complexe récepteur de l'élastine est impliqué dans ce mécanisme. Une analyse par cytométrie en flux confirme cette production de lactosylcéramide induite par les peptides d'élastine.L'analyse par spectrométrie de masse mettrait en évidence deux lactosylcéramides (C23:0 et C24:1) potentiellement bioactifs dont la synthèse chimique a été entreprise. La purification des radeaux lipidiques par ultracentrifugation différentielle en gradient de saccharose ainsi que leur identification par Dot-blot couplé à la fluorescence montre un changement de densité de ces microdomaines après stimulation par les peptides d'élastine.L'évaluation biologique in vitro de ces lactosylcéramides montre qu'ils miment les effets des peptides d'élastine sur l'activation de ERK 1/2, la prolifération et la synthèse de MMP-1. Enfin, l'évaluation ex vivo des lactosylcéramides démontre une réduction de la zone de tissu cardiaque nécrosé suggérant un rôle cardioprotecteur de ces molécules. Ce travail propose un mécanisme original de transduction du signal à la membrane plasmique et nous laisse envisager le complexe récepteur de l'élastine, les peptides d'élastine et le lactosylcéramide comme de nouveaux agents thérapeutiques potentiels. / Elastin is the matrix protein responsible for the elasticity of tissues where resilience is required such as lung, arteries or skin. Elastin degradation during physiopathological processes produces biologically active peptides named elastin peptides bearing the GXXPG pattern essential for their activity. These peptides regulate various biological functions such as chemotaxis, proteases synthesis and proliferation. These effects are dependent of elastin peptide binding to the elastin receptor complex (ERC). This complex is composed of three subunits: a peripheral protein of 67 kDa called elastin binding protein (EBP) and two membrane-associated proteins, protective protein/cathepsin A (PP/CA) and neuraminidase-1 (Neu-1) of 55 and 61 kDa, respectively. The sialidase activity of Neu-1 is responsible for ERK 1/2 pathway activation following binding of elastin peptide on the elastin receptor complex.In this study, we demonstrate that EBP and lipid rafts colocalize at the plasma membrane. We also show that the disruption of these microdomains and their depletion in glycolipids block the receptor signaling. The use of a monoclonal anti-GM3 blocking antibody shows that this glycosphingolipid is essential for signaling. Following elastin peptide treatment, cellular GM3 level decreases while the lactosylceramide one increases consistently with a GM3/LacCer conversion. The use of lactose or Neu-1 siRNA blocks this process suggesting that the elastin receptor complex is involved in this mechanism. Flow cytometry analysis confirms this elastin peptide-driven LacCer generation.Mass spectrometry analysis of elastin peptide-stimulated cell membrane extracts identified two potentially bioactive lactosylceramides (C23:0 and C24:1) and their synthesis has been realized. Lipid rafts purification by differencial ultracentrifugation in sucrose gradient shows a variation of the microdomains density as well as their identification by fluorescence linked-Dot-blot following elastin peptide stimulation.In vitro biological evaluation of these lactosylceramides shows that they mimic the elastin peptide effects on ERK 1/2 activation, proliferation and MMP-1 synthesis. Finally, ex vivo lactosylceramides evaluation demonstrates a decrease of cardiac tissue necrosis area suggesting that these molecules could be cardioprotective agents. This work proposes an original mechanism of signal transduction at the plasma membrane and let us foresees the elastin receptor complex, elastin peptides and lactosylceramide as new potential therapeutical targets.

Peptides d'élastine

Neuraminidase-1

Ganglioside GM3

Lactosylcéramide

Fibroblastes dermiques humains

Réparation tissulaire

Elastin peptide

Neuraminidase-1

GM3 ganglioside

Lactosylceramide

Human dermal fibroblasts

Tissue repair

Regulação de receptores de IGF e PDGF na musculatura esquelética de camundongos com deficiência de neuraminidase 1 / Regulation of IGF and PDGF receptors in the skeletal muscle of neuraminidase 1 deficient mice

Neves, Juliana de Carvalho

14 November 2018

A neuraminidase 1 (Neu1) é a enzima que regula o catabolismo de sialoglicoconjugados nos lisossomos. A deficiência da Neu1 é a base da sialidose, doença grave associada a um amplo espectro de manifestações, incluindo hipotonia e fraqueza muscular. Camundongos com deficiência de Neu1 desenvolvem degeneração muscular caracterizada principalmente por atrofia, invasão das fibras musculares por fibroblastos e expansão da matriz extracelular. A Neu1 controla a proliferação de fibroblastos de pacientes por meio da desialilação dos receptores de PDGF e IGF. Além disso, há enzimas lisossomais que são moduladas pela Neu1, tais como as catepsinas, que são capazes de degradar componentes musculares e estariam excessivamente ou erroneamente ativas (sialiladas) em decorrência da deficiência de Neu1. O objetivo deste trabalho foi identificar se o fenótipo da musculatura esquelética de camundongos Neu1-/- poderia estar associado à atividade do IGF-1R, PDGFR e/ou à sialilação de catepsina B, através da análise histológica e proteica de músculos esqueléticos e fibroblastos de camundongos Neu1+/+ e Neu1-/- tratados com inibidores de IGF1-R e PDGFR. O estudo da expressão proteica de catepsina B foi realizado nos músculos tratados com os inibidores de IGF-1R e PDGFR, e nas frações citosólica e lisossomal de fibroblastos tratados com neuraminidase exógena. Em comparação com camundongos Neu1+/+, os músculos de animais Neu1-/- apresentam menor área de fibra, peso corporal, expressão de pAkt e maior expressão de catepsina B; e os fibroblastos Neu1-/- exibem maior proliferação e expressão de pAkt. A inibição do IGF-1R em camundongos Neu1-/- aumentou a área das fibras musculares, expressão de pAKt e diminuiu a expressão de catepsina B; em relação aos fibroblastos Neu1-/-, entretanto aumentou a proliferação celular com diminuição de pAkt. A inibição do PDGFR em músculos de camundongos Neu1-/- levou ao aumento da expressão de pAkt, da área das fibras, com diminuição de pERK e catepsina L, quando comparados com os controles Neu1-/-; a mesma inibição in vitro conduziu à diminuição da expressão de pAkt, pERK e proliferação. A catepsina B encontra-se bastante ativa na fração lisossomal e o tratamento com neuraminidase foi eficaz na correção de seu peso molecular e compartimentalização lisossomal. De forma geral, o fenótipo muscular de camundongos Neu1-/- parece estar relacionado com a atividade de IGF-1R e PDGFR, e a catepsina B hipersialilada é potencialmente deletéria para o músculo esquelético / Neuraminidase 1 (Neu1) is an enzyme that regulates the catabolism of sialoglycoconjugates in lysosomes. Neu1 deficiency is the basis of sialidosis, a severe disease associated with a broad spectrum of manifestations, including hypotonia and muscle weakness. Neu1 deficient mice develop muscular degeneration characterized by atrophy, invasion of muscle fibers by fibroblasts, and expansion of the extracellular matrix. Neu1 controls the proliferation of fibroblasts from patients through the desialylation of PDGF and IGF receptors. In addition, lysosomal enzymes are modulated by Neu1, such as cathepsins, which degrade muscle components and are excessively or erroneously active (sialylated) as a result of Neu1 deficiency. The aim of this study was to identify whether skeletal muscle phenotype of Neu1-/- mice may be associated with IGF-1R, PDGFR and/or sialylation of cathepsin B, through protein and histological analysis of skeletal muscles and fibroblast from Neu1+/+ and Neu1-/- mice treated with IGF-1R and PDGFR inhibitors. The study of cathepsin B protein expression was performed in skeletal muscles treated with IGF-1R and PDGFR inhibitors, and in the cytosolic and lysosomal fractions of fibroblasts treated with exogenous neuraminidase. Compared with Neu1+/+ animals, Neu1-/- muscles showed smaller muscle fiber area, body weight, pAkt expression and higher cathepsin B expression; and Neu1-/- fibroblasts exhibited increased proliferation and expression of pAkt. The inhibition of IGF-1R Neu1-/- mice increased the area of muscle fibers, expression of pAkt and decreased expression of cathepsin B; but, considering Neu1-/- fibroblasts, there was increased cell proliferation with reduction of pAkt. The inhibition of PDGFR in muscles of Neu1-/- mice led to increased expression of pAkt, muscle fiber area, with decreased expression of pERK and cathepsin L, when compared with the Neu1-/- controls; the same inhibition in vitro led to reduced expression of pAkt, pERK and cell proliferation. Cathepsin B presented high activity in the lysosomal fraction and the treatment with neuraminidase was effective in the correction of its molecular weight and lysosomal compartmentalization. In general, the muscular phenotype of Neu1-/- mice is possibly related to IGF-1R and PDGFR activity, and oversialylated cathepsin B is potentially deleterious for the skeletal muscle

Catepsinas

Cathepsins

Fibroblastos

Fibroblasts

Insulin like growth factor receptor

Lisossomos

Lysosomes

Muscle skeletal

Músculo esquelético

Neuraminidase 1

Neuraminidase 1

Platelet-derived growth factor receptor

Regulação de receptores de IGF e PDGF na musculatura esquelética de camundongos com deficiência de neuraminidase 1 / Regulation of IGF and PDGF receptors in the skeletal muscle of neuraminidase 1 deficient mice

Juliana de Carvalho Neves

14 November 2018

A neuraminidase 1 (Neu1) é a enzima que regula o catabolismo de sialoglicoconjugados nos lisossomos. A deficiência da Neu1 é a base da sialidose, doença grave associada a um amplo espectro de manifestações, incluindo hipotonia e fraqueza muscular. Camundongos com deficiência de Neu1 desenvolvem degeneração muscular caracterizada principalmente por atrofia, invasão das fibras musculares por fibroblastos e expansão da matriz extracelular. A Neu1 controla a proliferação de fibroblastos de pacientes por meio da desialilação dos receptores de PDGF e IGF. Além disso, há enzimas lisossomais que são moduladas pela Neu1, tais como as catepsinas, que são capazes de degradar componentes musculares e estariam excessivamente ou erroneamente ativas (sialiladas) em decorrência da deficiência de Neu1. O objetivo deste trabalho foi identificar se o fenótipo da musculatura esquelética de camundongos Neu1-/- poderia estar associado à atividade do IGF-1R, PDGFR e/ou à sialilação de catepsina B, através da análise histológica e proteica de músculos esqueléticos e fibroblastos de camundongos Neu1+/+ e Neu1-/- tratados com inibidores de IGF1-R e PDGFR. O estudo da expressão proteica de catepsina B foi realizado nos músculos tratados com os inibidores de IGF-1R e PDGFR, e nas frações citosólica e lisossomal de fibroblastos tratados com neuraminidase exógena. Em comparação com camundongos Neu1+/+, os músculos de animais Neu1-/- apresentam menor área de fibra, peso corporal, expressão de pAkt e maior expressão de catepsina B; e os fibroblastos Neu1-/- exibem maior proliferação e expressão de pAkt. A inibição do IGF-1R em camundongos Neu1-/- aumentou a área das fibras musculares, expressão de pAKt e diminuiu a expressão de catepsina B; em relação aos fibroblastos Neu1-/-, entretanto aumentou a proliferação celular com diminuição de pAkt. A inibição do PDGFR em músculos de camundongos Neu1-/- levou ao aumento da expressão de pAkt, da área das fibras, com diminuição de pERK e catepsina L, quando comparados com os controles Neu1-/-; a mesma inibição in vitro conduziu à diminuição da expressão de pAkt, pERK e proliferação. A catepsina B encontra-se bastante ativa na fração lisossomal e o tratamento com neuraminidase foi eficaz na correção de seu peso molecular e compartimentalização lisossomal. De forma geral, o fenótipo muscular de camundongos Neu1-/- parece estar relacionado com a atividade de IGF-1R e PDGFR, e a catepsina B hipersialilada é potencialmente deletéria para o músculo esquelético / Neuraminidase 1 (Neu1) is an enzyme that regulates the catabolism of sialoglycoconjugates in lysosomes. Neu1 deficiency is the basis of sialidosis, a severe disease associated with a broad spectrum of manifestations, including hypotonia and muscle weakness. Neu1 deficient mice develop muscular degeneration characterized by atrophy, invasion of muscle fibers by fibroblasts, and expansion of the extracellular matrix. Neu1 controls the proliferation of fibroblasts from patients through the desialylation of PDGF and IGF receptors. In addition, lysosomal enzymes are modulated by Neu1, such as cathepsins, which degrade muscle components and are excessively or erroneously active (sialylated) as a result of Neu1 deficiency. The aim of this study was to identify whether skeletal muscle phenotype of Neu1-/- mice may be associated with IGF-1R, PDGFR and/or sialylation of cathepsin B, through protein and histological analysis of skeletal muscles and fibroblast from Neu1+/+ and Neu1-/- mice treated with IGF-1R and PDGFR inhibitors. The study of cathepsin B protein expression was performed in skeletal muscles treated with IGF-1R and PDGFR inhibitors, and in the cytosolic and lysosomal fractions of fibroblasts treated with exogenous neuraminidase. Compared with Neu1+/+ animals, Neu1-/- muscles showed smaller muscle fiber area, body weight, pAkt expression and higher cathepsin B expression; and Neu1-/- fibroblasts exhibited increased proliferation and expression of pAkt. The inhibition of IGF-1R Neu1-/- mice increased the area of muscle fibers, expression of pAkt and decreased expression of cathepsin B; but, considering Neu1-/- fibroblasts, there was increased cell proliferation with reduction of pAkt. The inhibition of PDGFR in muscles of Neu1-/- mice led to increased expression of pAkt, muscle fiber area, with decreased expression of pERK and cathepsin L, when compared with the Neu1-/- controls; the same inhibition in vitro led to reduced expression of pAkt, pERK and cell proliferation. Cathepsin B presented high activity in the lysosomal fraction and the treatment with neuraminidase was effective in the correction of its molecular weight and lysosomal compartmentalization. In general, the muscular phenotype of Neu1-/- mice is possibly related to IGF-1R and PDGFR activity, and oversialylated cathepsin B is potentially deleterious for the skeletal muscle

Catepsinas

Fibroblastos

Lisossomos

Músculo esquelético

Neuraminidase 1

Cathepsins

Fibroblasts

Insulin like growth factor receptor

Lysosomes

Muscle skeletal

Neuraminidase 1

Platelet-derived growth factor receptor