The Glucotoxicity Protecting Effect of Ezetimibe in Pancreatic Beta Cells via Inhibition of CD36

Inhibition of CD36, a fatty acid transporter, has been reported to prevent glucotoxicity and ameliorate high glucose induced beta cell dysfunction. Ezetimibe is a selective cholesterol absorption inhibitor that blocks Niemann Pick C1-like 1 protein, but may exert its effect through suppression of CD36. We attempted to clarify the beneficial effect of ezetimibe on insulin secreting cells and to determine whether this effect is related to change of CD36 expression. mRNA expression of insulin and CD36, intracellular peroxide level and glucose stimulated insulin secretion (GSIS) under normal (5.6 mM) or high glucose (30 mM) condition in INS-1 cells and primary rat islet cells were compared. Changes of the aforementioned factors with treatment with ezetimibe (20 μM) under normal or high glucose condition were also assessed. mRNA expression of insulin was decreased with high glucose, which was reversed by ezetimibe in both INS-1 cells and primary rat islets. CD36 mRNA expression was increased with high glucose, but decreased by ezetimibe in INS-1 cells and primary rat islets. Three-day treatment with high glucose resulted in an increase in intracellular peroxide level; however, it was decreased by treatment with ezetimibe. Decrease in GSIS by three-day treatment with high glucose was reversed by ezetimibe. Palmitate uptake following exposure to high glucose conditions for three days was significantly elevated, which was reversed by ezetimibe in INS-1 cells. Ezetimibe may prevent glucotoxicity in pancreatic β-cells through a decrease in fatty acid influx via inhibition of CD36.

Development of the endocrine pancreas and novel strategies for beta-cell mass restoration and diabetes therapy

Diabetes mellitus represents a serious public health problem owing to its global prevalence in the last decade. The causes of this metabolic disease include dysfunction and/or insufficient number of β cells. Existing diabetes mellitus treatments do not reverse or control the disease. Therefore, β-cell mass restoration might be a promising treatment. Several restoration approaches have been developed: inducing the proliferation of remaining insulin-producing cells, de novo islet formation from pancreatic progenitor cells (neogenesis), and converting non-β cells within the pancreas to β cells (transdifferentiation) are the most direct, simple, and least invasive ways to increase β-cell mass. However, their clinical significance is yet to be determined. Hypothetically, β cells or islet transplantation methods might be curative strategies for diabetes mellitus; however, the scarcity of donors limits the clinical application of these approaches. Thus, alternative cell sources for β-cell replacement could include embryonic stem cells, induced pluripotent stem cells, and mesenchymal stem cells. However, most differentiated cells obtained using these techniques are functionally immature and show poor glucose-stimulated insulin secretion compared with native β cells. Currently, their clinical use is still hampered by ethical issues and the risk of tumor development post transplantation. In this review, we briefly summarize the current knowledge of mouse pancreas organogenesis, morphogenesis, and maturation, including the molecular mechanisms involved. We then discuss two possible approaches of β-cell mass restoration for diabetes mellitus therapy: β-cell regeneration and β-cell replacement. We critically analyze each strategy with respect to the accessibility of the cells, potential risk to patients, and possible clinical outcomes.

Mecanismos moleculares envolvidos em citoproteção e transformação maligna de células-beta pancreáticas / Molecular mechanisms involved in pancreatic beta-cells cytoprotection and malignant transformation

O transplante de ilhotas pancreáticas constitui uma alternativa atraente para o tratamento de diabetes tipo 1 (DM1), contudo, é limitado devido à escassez de doadores de órgãos. O papel da prolactina humana recombinante (rhPRL), que apresenta efeitos benéficos em células-beta, e seu mecanismo de ação foram investigados neste estudo. O número de células apoptóticas diminui significativamente na presença de rhPRL. Essa citoproteção envolveu diminuição da razão BCL2/BAX e inibição de caspase-8, -9 e -3. Este estudo revelou, pela primeira vez, evidência direta do efeito protetor de lactogênios contra apoptose de células-beta humanas. Levando em consideração a relação conhecida entre citocinas e DM1 e observações recentes sugerindo o papel da autofagia no desenvolvimento e prevenção do DM1, foi investigada a conexão entre citocinas (IL-1ß, TNFα e IFN-γ) e autofagia em células-beta. O co-tratamento com citocinas e rapamicina, um indutor de autofagia via inibição de mTOR, não aumentou os níveis de apoptose em células INS-1E. Contudo, exposição a citocinas levou ao aumento nos níveis de autofagossomos e na relação LC3-II/LC3-I, do mesmo modo que o tratamento com rapamicina. O tratamento com citocinas também levou à diminuição dos níveis de mTOR e 4E-BP1 fosforilados. Foi demonstrada aqui, pela primeira vez, uma relação direta entre o tratamento com citocinas e a indução de autofagia em células-beta. Recentemente, surgiram novas evidências mostrando ligação entre a morte de células-beta induzida por citocinas e indução de estresse de retículo endoplasmático. Em nosso modelo, foram observados níveis diminuídos de p-mTOR e aumento da formação de autofagossomos após o tratamento com indutores de estresse de retículo. Este estudo reforça também, resultados prévios sobre a hipótese da função de indutores de estresse de retículo em promover a autofagia. Além disso, o tratamento com rhPRL aumentou os níveis de p-mTOR e levou à diminuição na formação de autofagossomos após exposição a citocinas em células-beta. Estes resultados são relevantes para a caracterização mais aprofundada das funções dos lactogênios nessas células. Sabendo-se da necessidade de células-beta humanas para estudos detalhados em células-beta, nosso grupo gerou linhagens celulares derivadas de insulinomas humanos que secretam hormônios e expressam marcadores com o mesmo padrão de seu tecido original. Estas linhagens foram caracterizadas comparando-as com culturas primárias de células-beta através de eletroforese bidimensional acoplada a espectrometria de massa. Cerca de 1.800 spots foram detectados, sendo que menos de 1% apresentou expressão diferencial. As proteínas superexpressas em ilhotas, como Caldesmon, estão envolvidas em organização do citoesqueleto, influenciando a secreção hormonal. Contrariamente, quase todas as proteínas superexpressas nas células de insulinoma, como MAGE-A2, foram descritas aqui pela primeira vez, podendo estar relacionadas à sobrevivência celular e resistência à quimioterapia. Estes resultados mostram, pela primeira vez, mudanças na expressão de proteínas relacionadas ao fenótipo alterado dos insulinomas, direcionando a pesquisa ao estabelecimento de células-beta humanas bioengenheiradas e ao desenvolvimento de novas estratégias terapêuticas para insulinomas. Coletivamente, os dados obtidos neste estudo estendem o conhecimento molecular envolvido na citoproteção induzida por rhPRL e transformação maligna de células-beta pancreáticas, contribuindo para futuras aplicações na compreensão e no tratamento do DM1

Transplantation of pancreatic islets constitutes an alternative for type 1 diabetes (DM1); however, it is limited by the shortage of organ donors. Here, we investigated the role of recombinant human prolactin (rhPRL), shown to have beneficial effects in beta-cells, and its mechanisms of action. Apoptotic beta-cells were decreased in the presence of rhPRL, with cytoprotection involving an increase of BCL2/BAX ratio and inhibition of caspase-8, -9 and -3. This study provides new direct evidence for a protective effect of lactogens in human beta-cell apoptosis. Taking into account the known relationship between cytokines and DM1 and recent observations suggesting a role for autophagy in the development and prevention of DM1, we investigated the connection between cytokines (IL-1ß, TNF-α and IFN-γ) and autophagy in beta-cells. Co-treatment with cytokines and rapamycin, an inducer of autophagy through inhibition of mTOR, did not increase the apoptosis levels in INS-1E cells. However, exposure to cytokines increased the levels of autophagosome formation and LC3-II/LC3-I ratio. Treatment with cytokines also led to decreased levels of phosphorylated mTOR and 4E-BP1. We demonstrated for the first time, a direct relationship between cytokines treatment and induction of autophagy in beta-cells. Lately, new evidence point to a connection between cytokine-induced beta-cell death and endoplasmic reticulum stress. In our model, we observed that decreased levels of p-mTOR and increased autophagosome formation also ensued after treatment with endoplasmic reticulum stressors. This study also supports the previous hypothesis on the function of ER stressors in inducing autophagy. Furthermore, rhPRL treatment increased the levels of p-mTOR and decreased autophagosome formation after exposure to cytokines in beta-cells. These findings are also relevant for further characterization of lactogens functions in these cells. Considering the demand for human cells for further beta-cells studies, our group generated cell lines derived from human insulinomas which secrete hormones and express markers with the same pattern displayed by their original tissue. We set out to further characterize these lineages by comparing them to primary beta-cells using two-dimensional gel electrophoresis coupled to mass spectrometry. An average of 1,800 spots was detected with less than 1% exhibiting differential expression. Proteins upregulated in islets, such as Caldesmon, are involved in cytoskeletal organization thus influencing hormone secretion. In contrast, almost all proteins upregulated in insulinoma cells, such as MAGE-A2, first described here, could be related to cell survival and resistance to chemotherapy. Our results provide, for the first time, a molecular snapshot of the changes in expression of proteins correlated with the altered phenotype of insulinomas, prompting research towards the establishment of bioengineered human beta-cells, and the development of new therapeutic strategies for insulinomas. Collectively, the data obtained in this study extend the molecular knowledge involved in rhPRL-induced cytoprotection and malignant transformation of pancreatic beta-cells, contributing to future applications for understanding and treatment of DM1

Differentiation of human labia minora dermis-derived fibroblasts into insulin-producing cells

Recent evidence has suggested that human skin fibroblasts may represent a novel source of therapeutic stem cells. In this study, we report a 3-stage method to induce the differentiation of skin fibroblasts into insulin-producing cells (IPCs). In stage 1, we establish the isolation, expansion and characterization of mesenchymal stem cells from human labia minora dermis-derived fibroblasts (hLMDFs) (stage 1: MSC expansion). hLMDFs express the typical mesenchymal stem cell marker proteins and can differentiate into adipocytes, osteoblasts, chondrocytes or muscle cells. In stage 2, DMEM/F12 serum-free medium with ITS mix (insulin, transferrin, and selenite) is used to induce differentiation of hLMDFs into endoderm-like cells, as determined by the expression of the endoderm markers Sox17, Foxa2, and PDX1 (stage 2: mesenchymal-endoderm transition). In stage 3, cells in the mesenchymal-endoderm transition stage are treated with nicotinamide in order to further differentiate into self-assembled, 3-dimensional islet cell-like clusters that express multiple genes related to pancreatic beta-cell development and function (stage 3: IPC). We also found that the transplantation of IPCs can normalize blood glucose levels and rescue glucose homeostasis in streptozotocin-induced diabetic mice. These results indicate that hLMDFs have the capacity to differentiate into functionally competent IPCs and represent a potential cell-based treatment for diabetes mellitus.

The Ability of beta-Cells to Compensate for Insulin Resistance is Restored with a Reduction in Excess Growth Hormone in Korean Acromegalic Patients

The aim of this study was to assess the prevalence of diabetes and to study the effects of excess growth hormone (GH) on insulin sensitivity and beta-cell function in Korean acromegalic patients. One hundred and eighty-four acromegalic patients were analyzed to assess the prevalence of diabetes, and 52 naive acromegalic patients were enrolled in order to analyze insulin sensitivity and insulin secretion. Patients underwent a 75 g oral glucose tolerance test with measurements of GH, glucose, insulin, and C-peptide levels. The insulin sensitivity index and beta-cell function index were calculated and compared according to glucose status. Changes in the insulin sensitivity index and beta-cell function index were evaluated one to two months after surgery. Of the 184 patients, 17.4% were in the normal glucose tolerance (NGT) group, 45.1% were in the pre-diabetic group and 37.5% were in the diabetic group. The insulin sensitivity index (ISI0,120) was significantly higher and the HOMA-IR was lower in the NGT compared to the diabetic group (P = 0.001 and P = 0.037, respectively). The ISI0,120 and disposition index were significantly improved after tumor resection. Our findings suggest that both insulin sensitivity and beta-cell function are improved by tumor resection in acromegalic patients.

Insulin is secreted upon glucose stimulation by both gastrointestinal enteroendocrine K-cells and L-cells engineered with the preproinsulin gene

Transgenic mice carrying the human insulin gene driven by the K-cell glucose-dependent insulinotropic peptide (GIP) promoter secrete insulin and display normal glucose tolerance tests after their pancreatic p-cells have been destroyed. Establishing the existence of other types of cells that can process and secrete transgenic insulin would help the development of new gene therapy strategies to treat patients with diabetes mellitus. It is noted that in addition to GIP secreting K-cells, the glucagon-like peptide 1 (GLP-1) generating L-cells share/ many similarities to pancreatic p-cells, including the peptidases required for proinsulin processing, hormone storage and a glucose-stimulated hormone secretion mechanism. In the present study, we demonstrate that not only K-cells, but also L-cells engineered with the human preproinsulin gene are able to synthesize, store and, upon glucose stimulation, release mature insulin. When the mouse enteroendocrine STC-1 cell line was transfected with the human preproinsulin gene, driven either by the K-cell specific GIP promoter or by the constitutive cytomegalovirus (CMV) promoter, human insulin co-localizes in vesicles that contain GIP (GIP or CMV promoter) or GLP-1 (CMV promoter). Exposure to glucose of engineered STC-1 cells led to a marked insulin secretion, which was 7-fold greater when the insulin gene was driven by the CMV promoter (expressed both in K-cells and L-cells) than when it was driven by the GIP promoter (expressed only in K-cells). Thus, besides pancreatic p-cells, both gastrointestinal enteroendocrine K-cells and L-cells can be selected as the target cell in a gene therapy strategy to treat patients with type 1 diabetes mellitus.

Dietary restriction prevents diabetogenic effect of streptozotocin in mice.

The beneficial role of dietary restriction (DR) was studied in streptozotocin (STZ)-induced diabetes in mice. The DR mice exhibited the lower blood glucose (mg/dl) level as compared to ad libitum (AL) fed ones. After 3 months’ DR, STZ treatment to both AL and DR mice showed significant (p<0.001) elevation of the blood glucose level in AL-fed mice, while a lower level of glucose was maintained in DR-fed mice. The ability of maintaining a low blood glucose level in STZ-treated DR mice indicated that STZ might have been ineffective from its action on beta cells of pancreas by long-term DR. Thus, these findings suggested that DR may be an important tool for preventing the diabetic conditions. However, further studies are required to know the mechanism(s) of DR protection against diabetogenic action of STZ in experimental animals.

Protection of INS-1 cells from free fatty acid-induced apoptosis by inhibiting the glycogen synthase kinase-3 / 华中科技大学学报（医学）（英德文版）

To examine the role of glycogen synthase kinase 3 (GSK-3) in the apoptosis of pancreatic beta-cells to better understand the pathogenesis and to find new approach to the treatment of type 2 diabetes, apoptosis was induced by oleic acid (OA) in INS-1 cells and the activity of GSK-3 was inhibited by LiCl. The PI staining and flow cytometry were employed for the evaluation of apoptosis. The phosphorylation level of GSK-3 was detected by Western blotting. The results showed that OA at 0.4 mmol/L could cause conspicuous apoptosis of INS-1 cells and the activity of GSK-3 was significantly increased. After the treatment with 24 mmol/L of LiCl, a inhibitor of GSK-3, the OA-induced apoptosis of INS-1 cells was lessened and the phosphorylation of GSK-3 was increased remarkably. It is concluded that GSK-3 activation plays an important role in OA-induced apoptosis in pancreatic beta-cells and inhibition of the GSK-3 activity can effectively protect INS-1 cells from the OA-induced apoptosis. Our study provides a new experimental basis and target for the clinical treatment of type-2 diabetes.

Coptidis rhizoma extract protects against cytokine-induced death of pancreatic beta-cells through suppression of NF-kappa B activation

We demonstrated previously that Coptidis rhizoma extract (CRE) prevented S-nitroso-N-acetylpenicillamine-induced apoptotic cell death via the inhibition of mitochondrial membrane potential disruption and cytochrome c release in RINm5F (RIN) rat insulinoma cells. In this study, the preventive effects of CRE against cytokine-induced beta-cell death was assessed. Cytokines generated by immune cells infiltrating pancreatic islets are crucial mediators of beta-cell destruction in insulin-dependent diabetes mellitus. The treatment of RIN cells with IL-1beta and IFN-gamma resulted in a reduction of cell viability. CRE completely protected IL-1beta and IFN-gamma-mediated cell death in a concentration-dependent manner. Incubation with CRE induced a significant suppression of IL-1beta and IFN-gamma-induced nitric oxide (NO) production, a finding which correlated well with reduced levels of the iNOS mRNA and protein. The molecular mechanism by which CRE inhibited iNOS gene expression appeared to involve the inhibition of NF-kappa B activation. The IL-1beta and IFN-gamma-stimulated RIN cells showed increases in NF-kappa B binding activity and p65 subunit levels in nucleus, and IkappaBalpha degradation in cytosol compared to unstimulated cells. Furthermore, the protective effects of CRE were verified via the observation of reduced NO generation and iNOS expression, and normal insulin-secretion responses to glucose in IL-1beta and IFN-gamma-treated islets.