Global ETD Search

171	Ilhotas pancreáticas humanas viáveis para o transplante através do aumento da massa de células e do imunoisolamento com microcápsulas biocompatíveis / Obtention of human pancreatic islets for transplantation through an increase in cell mass and an immunoisolation with biocompatible microcapsules Ana Carolina Vale Campos-Lisbôa 06 March 2009 (has links) O transplante de ilhotas pancreáticas humanas representa uma estratégia promissora para a cura do diabetes mellitus tipo 1 (DM1), mas a aplicação a todos os pacientes diabéticos ainda é impraticável devido à limitada disponibilidade de ilhotas ou células β e à necessidade de utilização de drogas imunossupressoras pelo paciente transplantado. O tratamento com imunossupressores após o transplante de ilhotas pode ser abolido quando se realiza o microencapsulamento das ilhotas pancreáticas. Neste trabalho investigou-se um novo biomaterial, Biodritina® (alginato/sulfato de condroitina) adequado ao microencapsulamento que gelifica na presença de íons de cálcio ou bário. A biocompatibilidade das microcápsulas tem sido avaliada segundo o grau de pureza do alginato utilizado na sua confecção. Amostras de alginato comercial purificado foram analisadas, comprovando-se a presença de impurezas (polifenóis, endotoxinas, proteínas) em níveis elevados, que impedem sua aplicação clínica. Optou-se, portanto pela utilização do alginato comercial ultrapurificado nos experimentos descritos neste trabalho. Das formulações de biomateriais avaliadas, as microcápsulas de bário-Biodritina apresentaram o melhor desempenho em testes de estabilidade físico-química. Estas microcápsulas mantiveram sua morfologia e estabilidade estrutural após permanecerem 30 dias na cavidade peritoneal de camundongos, conforme demonstrado por microscopia eletrônica de varredura (MEV). Análises histológicas mostraram que microcápsulas de bário-Biodritina explantadas, não possuíam adesão celular em sua superfície. Estudos de permeabilidade demonstraram que o tamanho médio dos poros das microcápsulas de bário-Biodritina permite passagem de proteínas de até 70 kDa, enquanto os poros daquelas de cálcio-Biodritina comportam proteínas de até 100 kDa. Experimentos de coResumo \| x cultivo de macrófagos peritoneais com ilhotas de rato microencapsuladas demonstraram uma capacidade imunoprotetora maior das microcápsulas de bário-Biodritina em relação às de cálcio- Biodritina, sendo que as primeiras não ativaram os macrófagos. A manutenção da viabilidade e função de ilhotas humanas microencapsuladas com bário-Biodritina foi confirmada através de ensaio funcional in vitro, no qual ilhotas microencapsuladas apresentaram níveis de secreção de insulina idênticos aos de ilhotas nuas. A prova de conceito do biomaterial foi realizada através do implante de ilhotas humanas microencapsuladas em bário-Biodritina em camundongos com DM1 induzido por estreptozotocina. A hiperglicemia desses animais foi corrigida pelo implante por um período superior a 60 dias, durante os quais o teste oral de tolerância à glicose mostrou-se normal, demonstrando completa funcionalidade e eficiência das ilhotas microencapsuladas com bário-Biodritina. Partindo de observações de que animais inoculados com a peçonha do escorpião Tityus serrulatus apresentam nesidioblastose, foi realizado o fracionamento do veneno por HPLC de fase reversa e 24 frações obtidas foram submetidas a ensaios de proliferação celular através da incorporação de 3H-timidina em células de insulinoma de rato RINm5F. Uma dessas frações foi capaz de induzir a proliferação das células RINm5F e quando aplicada a ilhotas humanas isoladas, elevou o índice de secreção de insulina e induziu um aumento da expressão dos mRNAs de insulina e PCNA. Portanto, demonstrou-se que o biomaterial bário-Biodritina possui as características necessárias para microencapsular células/ilhotas com eficiência e que a \"fração ativa\" do veneno do escorpião T. serrulatus induz proliferação de células RINm5F e melhora a secreção de insulina de ilhotas humanas. / Islet transplantation has been proposed as a promising therapeutic strategy for the cure of type 1 diabetes mellitus (DM), however, its application to all diabetic patients is still not possible due to the limited source of islets or β cells and to the need of an immunosuppressive treatment of the recipient to avoid graft rejection. The use of immunosupressors may be abolished when pancreatic islets are microencapsulated prior to transplantation. Here, we investigated the use of a new biomaterial suitable for cell microencapsulation, namely, Biodritin®, composed of alginate and chondroitin sulphate, which is capable of gelation in the presence of barium or calcium ions. Microcapsules biocompatibility has been evaluated according to the purity of the alginate used in its production. Samples of purified commercial alginate were analyzed, but the high levels of contaminants (proteins, endotoxins and polyphenols) detected prevented its use in clinical applications. On the other hand, also commercially available ultrapure alginate fulfills the requirements for this application, therefore, this biomaterial was chosen for our experiments. Among the different biomaterial formulations evaluated, barium-Biodritin microcapsules displayed the best performance in the physico-chemical tests. Scanning electronic microscopy revealed that barium-Biodritin microcapsules maintained their morphology and structural stability after being implanted for 30 days in the peritoneal cavity of mice. No cellular adhesion was detected on the surface of explanted barium-Biodritin microcapsules by histological analysis. Permeability studies determined the medium pore size of barium-Biodritin microcapsules, which allows proteins of up to 70 kDa to pass through the biomaterial, while calcium-Biodritin pores accomodate proteins of up to 100 kDa. Co-culture of peritoneal macrophages with microencapsulated rat islets, revealed a superior immunoprotective capacity of barium-Biodritin microcapsules, which were capable of protecting the islets with no macrophage activation. Microencapsulated and naked human islets presented identical insulin secretion levels upon stimulation with glucose in vitro, confirming that barium-Biodritin microencapsulation maintains the function and viability of human islets. Proof-of-concept experiments in which barium-Biodritin microencapsulated human islets were implanted into chemically-induced diabetic mice, showed that these animals maintained normal blood glucose levels for more than 60 days, during which oral glucose tolerance tests were normal, demonstrating the complete functionality and efficiency of barium-Biodritin microencapsulated human islets. From the observation that animals inoculated with the venom of the scorpion Tityus serrulatus presented nesidioblastosis, we decided to fractionate the venom to isolate the active principle. The venom was fractionated by reversed phase HPLC and 24 fractions were obtained and submitted to cellular proliferation assays, in which rat insulinoma RINm5F cells evaluated for 3H-timidina incorporation. One of these fractions was capable of inducing cell proliferation and was also applied to isolated human islets. Treated islets presented a higher insulin secretion index and an increase in insulin and PCNA mRNA expression. In conclusion, we demonstrated that the barium-Biodritin biomaterial possesses all characteristics required for efficient cell/islet microencapsulation and that the active fraction of Tityus serrulatus venom induces the proliferation of RINm5F cells and improves insulin secretion in human islets. Biologia celular Diabetes mellitus tipo 1 Ilhotas pancreáticas de Langerhans Microencapsulamento de ilhotas Proliferação de células beta Transplante de ilhotas Transplante de pâncreas Veneno de escorpião Beta cell proliferation Celular biology Islet microencapsulation Islet transplantation Pancreatic islets of Langerhans Scorpion venom Type 1 Diabetes mellitus
172	Caractérisation du rôle de l’amyline (IAPP) dans le diabète de type 2 : études de dérivés peptidiques et de composés inhibiteurs de la formation d’amyloïde Fortin, Jessica 06 1900 (has links) L’amyloïdose, une maladie progressive et incurable, implique une vaste panoplie de pathologies et de pathogénèses, qui est expliquée par la grande variabilité biologique et structurale des protéines responsables de la formation des dépôts d’amyloïde. L’amyline (polypeptide amyloïde des îlots pancréatiques, IAPP) est une protéine très susceptible de subir des changements de conformation impliquant les feuillets bêta et conférant aussi des propriétés physicochimiques distinctes. Cette protéine prend alors une forme fibrillaire et se dépose dans les îlots de Langerhans chez les humains atteints de diabète de type 2 ou d’insulinome. Ces dépôts d’amyloïde pancréatique (AIAPP) ont été décrits chez certaines espèces animales telles que les félins domestiques, les grands félins, le raton laveur et les primates non humains. La formation de dépôts d’amyloïde contribue à la pathogénèse du diabète de type 2, mais les mécanismes qui induisent la conversion de l’amyline (IAPP) en amyloïde (AIAPP) ne sont pas complètement compris. Les hypothèses du projet sont que certaines variations présentes dans les séquences peptidiques de l’IAPP provenant de différentes espèces animales jouent un rôle critique pour la formation de fibrilles et que plusieurs composés chimiques aromatiques/phénoliques sont capables d’abroger la formation de dépôts d’amyloïde. Le projet de recherche consiste donc à caractériser la propension des différentes isoformes animales d’IAPP à former de l’amyloïde in vitro afin d’identifier les acides aminés jouant un rôle clé dans cette transformation structurale et ultimement d’inhiber la formation d’amyloïde pancréatique. Le projet se divise en deux volets principaux. Le premier consiste à identifier les différentes séquences peptidiques de l’IAPP retrouvées chez les espèces animales. L’objectif est d’identifier les acides aminés jouant un rôle clé dans la formation d’amyloïde. Le gène de l’IAPP a été séquencé chez plus d’une quarantaine d’espèces. Le potentiel d’agrégation des séquences obtenues a été simulé à l’aide d’outils bioinformatique. Une librairie de 23 peptides a été commandée afin de procéder à des analyses physicochimiques in vitro permettant d’évaluer le potentiel amyloïdogénique (test fluorimétrique à la thioflavine T, essai de liaison au rouge Congo, dichroïsme circulaire, microscopie électronique à transmission) et cytotoxique (sur une lignée cellulaire provenant d’insulinome : INS-1). Les analyses effectuées à partir de la librairie constituée de 23 peptides ont permis d’identifier trois séquences ne formant pas d’amyloïde et qui proviennent des espèces animales suivantes : le tamarin lion doré (Leontopithecus rosalia), le grand dauphin (Tursiops truncatus) et l’alpaga (Vicugna pacos). Un site potentiellement critique est le segment 8-20 présentant le motif NFLVH qui ne forme plus d’amyloïde lorsqu’il est remplacé par le motif DFLGR ou KFLIR. Les acides aminés 29P, 14K et 18R sont également impliqués dans l’inhibition de la transformation structurale en fibrille. La dernière partie du projet consiste à inhiber la formation de l’amyloïde en utilisant des composés chimiques commercialisés (hypoglycémiants, anti-inflammatoires non stéroïdiens) ou nouvellement synthétisés dans notre laboratoire (les aryles éthyles urées). Un criblage d’une soixantaine de composés chimiques a été conduit dans cette étude. Leur efficacité a été testée sur l’IAPP humaine, qui possède un fort potentiel amyloïdogénique. Les techniques utilisées sont les mêmes que celles exploitées précédemment. L’essai de liaison croisée photo-induite ("photo-induced cross-linking of unmodified proteins", PICUP) a été réalisé afin d’étudier les formes intermédiaires (monomères, oligomères). Un total de 11 composés chimiques a démontré un potentiel à inhiber l’agrégation des fibrilles. Pour la classe des hypoglycémiants, le glyburide, le répaglinide et la troglitazone ont montré l’activité thérapeutique la plus élevée pour retarder et réduire la formation de fibrilles. Les anti-inflammatoires antiamyloïdogènes actifs incluaient le diclofenac, le méloxicam, le phénylbutazone, le sulindac et le ténoxicam. Les aryles étyles urées les plus intéressantes étaient la EU-362 et la EU-418. Tous ces composés ont conféré une protection cellulaire contre l’activité cytotoxique des fibrilles. Les molécules actives possèdent des éléments structuraux communs tels des substituants donneurs d’électrons (alcool, amine, halogène) sur un noyau benzène. En conclusion, ce projet de recherche a permis de caractériser l’IAPP chez diverses espèces animales, dont plusieurs chez lesquelles elle n’avait pas encore été décrite, de déterminer les sites jouant un rôle clé dans sa transformation en amyloïde et, ultimement, de tester le potentiel thérapeutique de nouveaux agents antiamyloïdogènes dans le diabète de type 2. Nous espérons que ce projet ouvrira ainsi la porte à de nouvelles stratégies de traitement. / Amyloidosis is a progressive and, as of now, incurable disease caused by the deposition of insoluble proteins. Amyloid research over the past decades focused on the characterization of the substantive biological variability of amyloid deposits. Amyloidosis encompasses a diversity of pathological manifestations, explained by the diversity of underlying causal proteins. In the pancreas of susceptible species, islet amyloid polypeptide (IAPP) is a precursor for an amyloid protein (AIAPP), which has a characteristic fibrillar structure and resistance to physical agents. This folded protein deposits in the islets of Langerhans of patients with type 2 diabetes or islet cell tumors (insulinoma). Amyloid deposits have also been well characterized, anatomically, in feline and non-human primate species. Amyloid fibril formation contributes to the pathogenesis of diabetes mellitus but the precise pathophysiologic factors involved in the fibrillization of IAPP as well as resultant islet injury remain to be elucidated. Further understanding of the causative factors in the fibrillogenesis of IAPP will be requisite in the development of therapeutic strategies to disrupt the amyloidosis process. This project hypothesizes that the specific variations found in IAPP peptide sequences among different animal species are critical for IAPP fibrillization. Also, some aromatic/polyphenolic compounds can abrogate fibrillization. The main objective forms the basis for development of new therapeutic tactics to impede amyloid formation and associated cellular injury. Thus this project has two specific aims. The first specific aim was to identify critical variations in IAPP amino acid sequences from different animal species and to assess their amyloidogenic potential. To accomplish this, the IAPP gene was isolated and sequenced from paraffin-embedded tissues from various animals (40 species). The aggregation potency was assessed for each sequence using in silico analysis. A library of 23 peptides was prepared from sequences that were distinctly different and their amyloidogenic potential was assessed in vitro using physicochemical analysis (thioflavin-T assay, Congo red binding assay, far-UV circular dichroism, transmission electron microscopy) and cytotoxicity assays (insulinoma cell line INS-1). Among this peptide library, three were non-amyloidogenic and corresponded to the following animal species: golden lion tamarin (Leontopithecus rosalia), commun bottlenose dolphin (Tursiops truncates) and alpaca (Vicugna pacos). Segment 8-20 of the peptide was critical for amyloid formation and the substitution of the NFLVH motif found in this region by a DFLGR or KFLIR motif impeded fibrillization. The amino acids 29P, 14K and 18R were also demonstrated to abrogate fibril formation. The second objective consisted in abrogating IAPP fibrillogenesis using conceptualized aromatic/polyphenolic structures, specifically hypoglycemic, non-steroidal anti-inflammatory and aryl ethyl urea agents. This part of the project involved molecular screening of more than 60 compounds. Their efficacy at inhibiting amyloid formation was assessed in vitro on human IAPP, which exhibits the highest amyloidogenic potential. Techniques included the above-mentioned methods, with the addition of photo-induced cross-linking of unmodified proteins (PICUP). A total of 11 compounds showed potential in abrogating IAPP aggregation. Among the hypoglycemic agents evaluated, glyburide, repaglinide and troglitazone showed the highest potency in reducing fibril formation. The NSAIDs that displayed anti-amyloidogenic activity were diclofenac, meloxicam, phenylbutazone, sulindac and tenoxicam. EU-362 and EU-418 were the hit compounds resulting from the screening of the aryl ethyl urea (EU) class. Additionally, these anti-amyloidogenic molecules conferred a protection against fibril cytotoxicity. All of the active molecules bear a commun motif composed of benzene ring with electron donor moieties, such as alcohol, amine or halide. To conclude, this project characterized IAPP in several animal species in which it has not been previously described and improves our understanding of the amyloidogenesis process. Moreover, the therapeutic potential of hypoglycemic, non-steroidal anti-inflammatory and aryl ethyl ureas agents as anti-amyloidogenic compounds was evaluated. It is conceivable that the additional information hereby gained on the regulation of amyloidogenesis may point towards new therapeutic strategies for diabetic patients. amyline amyloïde analogues peptidiques diabète de type 2 îlot de Langerhans pancréas amyloid islet amyloid polypeptide (IAPP) inhibitors of fibrillization pancreas islets of Langerhans peptide analogues type 2 diabetes
173	Treinamento aeróbio de intensidade moderada mantém a viabilidade celular de ilhotas pancreáticas e previne a perda da resposta secretora de insulina à glicose em camundongos alimentados com dieta hipercalórica. / Moderate aerobic training maintains pancreatic islet cellular viability and prevents glucose stimulated insulin secretion impairment in mice fed a hypercaloric diet. Véras, Katherine Maria de Araujo 01 November 2016 (has links) Os efeitos do treinamento aeróbio moderado sobre a viabilidade celular e a GSIS das ilhotas pancreáticas foram investigados em camundongos C57BL/6 alimentados com dieta rica em lipídios (60%) e sacarose (20%) (HFDS). Os grupos foram: HFDS, dieta controle (C), HFDS treinado (HFDSTR), controle treinado (CTR). Após 8 semanas, houve aumentada massa corporal e adiposidade e diminuída tolerância à glicose e sensibilidade à insulina no HFDS; tais efeitos foram atenuados em HFDSTR. Houve menor percentual de células viáveis e prejudicada GSIS no HFDS do que no HFDSTR e C. As expressões do GLUT2 e da CuZn superóxido dismutase-1 (SOD1) foram diminuídas em HFDS, mas não no HFDSTR. As respostas observadas nas ilhotas do grupo HFDSTR foram semelhantes ao grupo C. O treinamento aeróbio de 8 semanas preveniu os efeitos deletérios da HFDS sobre a sensibilidade à insulina, viabilidade celular e GSIS e manteve o conteúdo enzimático antioxidante endógeno, sugerindo que o treinamento aeróbio possa ser benéfico na prevenção dos efeitos deletérios de uma HFDS. / This study investigated the aerobic training effects on GSIS and pancreatic islet cellular viability in C57BL/6 mice fed a high fat (60%) and sucrose (20%) diet (HFDS). The groups were: HFDS, control diet (C), HFDS + training (HFDSTR) and control trained (CTR). After 8 weeks the HFDS significantly increased body mass and adiposity, decreased glucose tolerance and insulin sensitivity, and impaired GSIS and cellular viability; these effects were attenuated in HFDSTR. There were less viable pancreatic islets cells and impaired GSIS in HFDS than in HFDSTR and C. The decreased GLUT 2 and CuZn-superoxide dismutase 1 (SOD1) protein expression in HFDS were increased in HFDSTR. Most pancreatic islet responses were similar between HFDSTR and C. Eight weeks aerobic training prevented deleterious effects of HFDS on insulin sensitivity, cellular viability and GSIS, and maintained endogenous antioxidant enzyme content, thus suggesting that aerobic training may be beneficial to prevent adverse metabolic effects associated with westernized diet consuming. Aerobic training Cellular viability Dieta rica em lipídio e sacarose GSIS GSIS High fat diet and sucrose Ilhotas pancreáticas Pancreatic islet Prevenção Prevention SOD1 and GLUT2 SOD1 e GLUT2 Treinamento aeróbio Viabilidade celular
174	"Clonagem e caracterização de genes regulados por glicose em ilhotas pancreáticas humanas" / Cloning and characterization of glucose-regulated genes in human pancreatic islets Aita, Carlos Alberto Mayora 16 December 2002 (has links) O Diabetes mellitus (DM) do tipo 1 é uma doença causada pela destruição, por mecanismo auto-imune, das células beta das ilhotas pancreáticas, produtoras de insulina. O tratamento convencional da doença é realizado por meio de injeções diárias de insulina exógena. O transplante de ilhotas pancreáticas inclui-se, atualmente, como uma das alternativas terapêuticas à insulinoterapia. Entretanto, para atingir a insulino-independência, é necessário transplantar um grande número de ilhotas por paciente. O conhecimento do mecanismo de proliferação das células beta pode possibilitar a realização do transplante a partir da expansão celular ex vivo. A glicose é um dos principais indutores da proliferação de células beta. Neste trabalho, foi estabelecida e executada a tecnologia de isolamento e purificação de ilhotas pancreáticas humanas, visando sua estimulação com glicose. Para identificar genes regulados por glicose nestas ilhotas, foi utilizada a técnica de hibridização subtrativa SSH, associada ao rastreamento da biblioteca através de macroarranjos de DNA. Num primeiro rastreamento, foram identificados dois fragmentos gênicos induzidos pela glicose. Um destes apresentou homologia com uma proteína hipotética humana de função desconhecida e o segundo com o receptor de polipetídeo pancreático. Este trabalho permitiu a identificação de novos genes regulados pela glicose em ilhotas pancreáticas humanas, os quais podem estar relacionados à proliferação celular deste tecido. / Type 1 Diabetes mellitus (T1DM) is caused by autoimmune destruction of the insulin-producing pancreatic islet b-cells. Treatment is generally approached by daily subcutaneous injections of exogenous insulin. Nowadays, pancreatic islet transplantation is considered as an effective alternative treatment to insulin therapy. However, in order to reach insulin-independence, a large number of islets is required for each patient. Knowledge of the mechanisms regulating islet b-cell proliferation may allow ex-vivo b-cell expansion prior to transplant. Glucose is considered one of the main inducers of islet b-cells proliferation. We established and executed the technology of human islet isolation and purification. The islets were then stimulated in culture with glucose. In order to identify glucose-regulated genes in cultured human islets, we utilized the suppression subtractive hybridization (SSH) method, followed by cDNA library screening by DNA macroarrays. Preliminary screening allowed us to isolate two cDNAs displaying glucose regulation, one of which is similar to a human hypothetical protein of unknown function and the other shows similarity to the pancreatic polypeptide receptor. This work allowed identification of glucose-regulated genes in human pancreatic islets, which may be related to cell proliferation in this tissue. beta cell proliferation clonagem gênica diabetes mellitus do tipo 1 gene cloning glicose glucose hibridização subtrativa human pancreatic islets ilhotas pancreáticas humanas islet transplantation proliferação de células beta suppression subtractive hybridization transplante de ilhotas type 1 diabetes mellitus
175	Phycocyanin protects INS-1E pancreatic beta cells against human islet amyloid polypeptide-induced apoptosis through attenuating oxidative stress and mitochondrial dysfunction. / CUHK electronic theses & dissertations collection January 2010 (has links) Additionally, cyclosporin A, an inhibitor of the mitochondrial permeability transition (MPT) pore, failed to prevent hIAPP-induced DeltaPsim collapse, cytochrome c and AIF release and caspase-3 activation, indicating that the MPT pore was not involved in hIAPP-induced apoptosis. On the other hand, potential crosstalk between the extrinsic and intrinsic apoptotic pathways was demonstrated by cleavage of Bid by caspase-8 in the apoptotic process triggered by hIAPP. / It is widely accepted that human islet amyloid polypeptide (hIAPP) aggregation plays an important role in the loss of insulin-producing pancreatic beta cells. Insulin secretion impairment and cell apoptosis can be due to mitochondrial dysfunction in pancreatic beta cells. hIAPP-induced cytotoxicity is mediated by the generation of reactive oxygen species (ROS). Phycocyanin (PC) is a natural compound from blue-green algae that is widely used as food supplement. Currently, little information is available about the effect of hIAPP on mitochondrial function of beta cells and protection of PC against hIAPP-induced cytotoxicity. In this thesis, I hypothesize that hIAPP may impair beta cell function with the involvement of mitochrondrial dysfunction, and this effects could be attenuated by PC. Therefore, the aim of this study was to investigate the role of mitochondria in hIAPP-induced apoptosis, the in vitro protective effects of PC and explore the underlying mechanisms. / It was found that hIAPP induced apoptosis in INS-1E cells with the disruption of mitochondrial function, as evidenced by ATP depletion, mitochondrial mass reduction, mitochondrial fragmentation and loss of mitochondrial membrane potential (DeltaPsim). Further molecular analysis showed that hIAPP induced changes in the expression of Bcl-2 family members, release of cytochrome c and apoptosis-inducing factor (AIF) from mitochondria into cytosol, activation of caspases and cleavage of poly (ADP-ribose) polymerase. Interestingly, the hIAPP-induced mitochondrial dysfunction in INS1-E cells was effectively restored by co-treatment with PC. / Our results showed that hIAPP inhibited the INS-1E cell growth in a dose-dependent manner. However, cytotoxicity of hIAPP was significantly attenuated by co-incubation of the cells with PC. hIAPP induced DNA fragmentation and chromatin condensation, which were key characteristics of cell apoptosis. These changes were inhibited by PC as examined by TUNEL assay and DAPI staining. Moreover, PC significantly prevented the hIAPP-induced overproduction of intracellular ROS and malonaldehyde (MDA), as well as changes of activities of superoxide dismutase (SOD) and glutathione peroxidase (GSH-Px) enzymes. Furthermore, hIAPP triggered the activation of mitogen-activated protein kinases (MAPKs) such as c-Jun N-terminal kinase (JNK) and p38 kinase, and these effects were effectively suppressed by PC. / Taken together, I have demonstrated for the first time the involvement of mitochondrial dysfunction in hIAPP-induced INS-1E cell apoptosis, which was attenuated by PC through attenuating oxidative stress, modulating JNK and p38 pathways and reducing mitochondrial dysfunction. / Li, Xiaoling. / Adviser: Juliana Chung Ngor Chan. / Source: Dissertation Abstracts International, Volume: 73-01, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 150-159). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. Apoptosis Mitochondrial pathology Pancreatic beta cells Peptide hormones Phycobiliproteins Apoptosis Diabetes Mellitus, Type 2--drug therapy Insulin-Secreting Cells--secretion Islet Amyloid Polypeptide Mitochondrial Diseases Phycocyanin--therapeutic use
176	Islet insulin secretory patterns in diabetes and the role of UCP2 Lin, Jian-Man January 2002 (has links) <p>During development of type 1 and type 2 diabetes plasma insulin patterns are altered. Since the islet insulin release pattern has been implicated in this development, insulin secretion from single islets was studied and linked to the islet protein levels of uncoupling protein-2 (UCP2). Islets were isolated from NOD- and KKA<sup>y</sup>- mice, GK- and GK-derived congenic rats, which are animal models of diabetes, and three human subjects with type 2 diabetes. At basal glucose (3 mM), insulin release from such islets was pulsatile and the amount released was comparable to that of control islets. When the glucose concentration was raised to 11 mM insulin release was essentially unchanged in islets isolated from older NOD- and KKA<sup>y</sup>- mice, GK- and Niddm1i congenic rats, and NIDDM persons. In islets from Niddm1f congenic rats, younger NOD- and KKA<sup>y</sup>-mice, control animals and normal human donors the secretion rate increased 2-9 fold when the glucose concentration was raised. This rise in secretion was manifested as increase of the amplitude of the insulin oscillations without affecting their frequency. Impaired glucose-induced insulin release was associated with reduction in glucose oxidation measured in NOD-islets, unaffected respiration measured in GK-islets and higher protein level of UCP2 measured in KKA<sup>y</sup>-islets. When the UCP2 amounts in KKA<sup>y</sup>-islets were reduced by culture to those of control islets, glucose-induced insulin secretion was essentially normalized. Our studies suggest that the deranged plasma insulin patterns observed in diabetes are related to decrease in the amplitude of insulin oscillations from the islets rather than loss of the oscillatory activity. This reduction of pulse amplitude may be related to impaired glucose metabolism and/or increased mitochondrial uncoupling. </p> Cell biology type 1 diabetes type 2 diabetes NOD GK congenes KKAy human islet glucose insulin release oscillation frequency amplitude oxidation respiration UCP2 western blot Cellbiologi Cell biology Cellbiologi
177	Glucotoxicity in Insulin-Producing β-Cells Nyblom, Hanna K January 2007 (has links) <p><b>Background and aims:</b> Type 2 diabetes mellitus is connected with elevated glucose levels, which cause impaired glucose-stimulated insulin secretion (GSIS) and degeneration of β-cells. Mechanisms for such glucotoxic effects were explored in the present study.</p><p><b>Materials and methods:</b> INS-1E cells were cultured for 5 days in 5.5, 11, 20 or 27 mM glucose in the presence or absence of AMPK-agonist AICAR. GSIS was determined from INS-1E cells and islets obtained from type 2 diabetes and control donors. Human islets and INS-1E cells were functionally characterized (GSIS) and protein profiled (SELDI-TOF MS). Glucose-induced <i>de novo</i> synthesis of fatty acyls (HR-MAS NMR spectroscopy), fatty acid composition (GC-MS), triglyceride content and specific proteins (Western blotting) were determined in INS-1E cells.</p><p><b>Results:</b> Impaired GSIS was observed from INS-1E cells exposed to chronic hyperglycaemia and islets isolated from type 2 diabetics compared to INS-1E cells cultured at normal glucose levels and control islets, respectively. Several glucose-regulated proteins were found when type 2 diabetes and control islets or mitochondria from INS-1E cells cultured at different glucose concentrations were protein profiled. Glucose induced lipid <i>de novo</i> synthesis of both saturated and unsaturated fatty acids in specific proportions. Glucose-induced impairment of function and mass was reverted by inclusion of AICAR, which lowered levels of pro-apoptotic protein CHOP but left triglyceride content unaffected.</p><p><b>Conclusions:</b> Impaired GSIS and increased apoptosis observed in β-cells after prolonged exposure to elevated glucose concentrations involved accumulation of lipid species in specific proportions, AMPK-inactivation, ER-stress activation and complex, coordinated changes in expression patterns of mitochondrial and human islet proteins.</p> Cell biology type 2 diabetes SELDI-TOF MS glucotoxicity proteomics insulin secretion mitochondria lipids INS-1E cells GC-MS HR-MAS NMR metabolomics human islet AMPK AICAR ER stress apoptosis Cellbiologi
178	Islet insulin secretory patterns in diabetes and the role of UCP2 Lin, Jian-Man January 2002 (has links) During development of type 1 and type 2 diabetes plasma insulin patterns are altered. Since the islet insulin release pattern has been implicated in this development, insulin secretion from single islets was studied and linked to the islet protein levels of uncoupling protein-2 (UCP2). Islets were isolated from NOD- and KKAy- mice, GK- and GK-derived congenic rats, which are animal models of diabetes, and three human subjects with type 2 diabetes. At basal glucose (3 mM), insulin release from such islets was pulsatile and the amount released was comparable to that of control islets. When the glucose concentration was raised to 11 mM insulin release was essentially unchanged in islets isolated from older NOD- and KKAy- mice, GK- and Niddm1i congenic rats, and NIDDM persons. In islets from Niddm1f congenic rats, younger NOD- and KKAy-mice, control animals and normal human donors the secretion rate increased 2-9 fold when the glucose concentration was raised. This rise in secretion was manifested as increase of the amplitude of the insulin oscillations without affecting their frequency. Impaired glucose-induced insulin release was associated with reduction in glucose oxidation measured in NOD-islets, unaffected respiration measured in GK-islets and higher protein level of UCP2 measured in KKAy-islets. When the UCP2 amounts in KKAy-islets were reduced by culture to those of control islets, glucose-induced insulin secretion was essentially normalized. Our studies suggest that the deranged plasma insulin patterns observed in diabetes are related to decrease in the amplitude of insulin oscillations from the islets rather than loss of the oscillatory activity. This reduction of pulse amplitude may be related to impaired glucose metabolism and/or increased mitochondrial uncoupling. Cell biology type 1 diabetes type 2 diabetes NOD GK congenes KKAy human islet glucose insulin release oscillation frequency amplitude oxidation respiration UCP2 western blot Cellbiologi Cell biology Cellbiologi
179	Glucotoxicity in Insulin-Producing β-Cells Nyblom, Hanna K January 2007 (has links) <b>Background and aims:</b> Type 2 diabetes mellitus is connected with elevated glucose levels, which cause impaired glucose-stimulated insulin secretion (GSIS) and degeneration of β-cells. Mechanisms for such glucotoxic effects were explored in the present study. <b>Materials and methods:</b> INS-1E cells were cultured for 5 days in 5.5, 11, 20 or 27 mM glucose in the presence or absence of AMPK-agonist AICAR. GSIS was determined from INS-1E cells and islets obtained from type 2 diabetes and control donors. Human islets and INS-1E cells were functionally characterized (GSIS) and protein profiled (SELDI-TOF MS). Glucose-induced de novo synthesis of fatty acyls (HR-MAS NMR spectroscopy), fatty acid composition (GC-MS), triglyceride content and specific proteins (Western blotting) were determined in INS-1E cells. <b>Results:</b> Impaired GSIS was observed from INS-1E cells exposed to chronic hyperglycaemia and islets isolated from type 2 diabetics compared to INS-1E cells cultured at normal glucose levels and control islets, respectively. Several glucose-regulated proteins were found when type 2 diabetes and control islets or mitochondria from INS-1E cells cultured at different glucose concentrations were protein profiled. Glucose induced lipid de novo synthesis of both saturated and unsaturated fatty acids in specific proportions. Glucose-induced impairment of function and mass was reverted by inclusion of AICAR, which lowered levels of pro-apoptotic protein CHOP but left triglyceride content unaffected. <b>Conclusions:</b> Impaired GSIS and increased apoptosis observed in β-cells after prolonged exposure to elevated glucose concentrations involved accumulation of lipid species in specific proportions, AMPK-inactivation, ER-stress activation and complex, coordinated changes in expression patterns of mitochondrial and human islet proteins. Cell biology type 2 diabetes SELDI-TOF MS glucotoxicity proteomics insulin secretion mitochondria lipids INS-1E cells GC-MS HR-MAS NMR metabolomics human islet AMPK AICAR ER stress apoptosis Cellbiologi
180	Prevention of type 1 diabetes mellitus in experimental studies Holstad, Maria January 2001 (has links) The aim of the study was to examine the immune response and different immunoprotective strategies in experimental type 1 diabetes mellitus. The autoimmune destruction of the insulin-producing pancreatic β-cells that leads to type 1 diabetes is complex and incompletely understood. Activated immune cells infiltrate the pancreatic islets at an early stage of the disease, and they produce and release cytokines, which may contribute to β-cell dysfunction and death. Several immunomodulatory agents with different mechanisms have recently been developed in order to suppress cytokine function such as MDL 201, 449A, a novel transcriptional inhibitor of TNF-α. At least in rodent β-cells, many of the toxic actions of cytokines depend on the synthesis of nitric oxide (NO). Aminoguanidine (AG), an inhibitor of NO formation, might therefore be an interesting compound for prevention of type 1 diabetes. Another substance that could influence the course of events leading to this disease is the pituitary hormone prolactin (PRL), since it has the ability to activate different immune cells. We have studied the effects of AG, PRL and MDL 201, 449A on the development of hyperglycaemia and pancreatic insulitis in multiple low dose streptozotocin induced autoimmune diabetes in mice. The natural course after syngeneic islet transplantation of pancreatic islets in NOD mice, a model of type 1 diabetes mellitus was also investigated. AG and PRL were also studied in vitro on cultured isolated rodent pancreatic islets. We suggest that the insulin-producing cells are specifically targeted by the inflammatory response after syngeneic islet transplantation in type 1 diabetic mice. Our data do not exclude a role for NO in type 1 diabetes, but it raises concerns about the use of AG as a therapeutic agent since an increased mortality and no decline in diabetes frequency was observed. AG did not seem to be directly harmful to β-cell function, but it could affect pancreatic and islet blood flows. PRL and MDL 201, 449A could both counteract hyperglycaemia and insulitis in the early phase of autoimmune diabetes. Cell biology Cytokines inducible nitric oxide synthase nitric oxide NOD mice pancreatic islets prolactin syngeneic islet transplantation tumour necrosis factor alpha type 1 diabetes mellitus Cellbiologi Cell biology Cellbiologi

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