Metabolic regulation of insulin secretion: the link between excess glucose, mechanistic target of rapamycin complex 1 & hyperinsulinemia

Rumala, Courtney

07 October 2019

Obesity, a major risk factor in the development of Type 2 Diabetes (T2D), is commonly associated with insulin resistance and hyperinsulinemia. The long accepted view has been that insulin resistance drives hyperinsulinemia; however, there are multiple lines of evidence that hyperinsulinemia can precede and drive insulin resistance. The signals and mechanisms by which chronic excess nutrients promote pancreatic β-cell dysfunction remain poorly understood. This prompted us to define the signaling events that contribute to basal insulin hypersecretion induced by excess glucose. Of particular interest is signaling through mechanistic target of rapamycin complex 1 (mTORC1), a nutrient sensitive kinase complex whose hyperactivation has been shown to promote hyperinsulinemia. Clonal ß-cells (INS-1 cells) with and without mTORC1 inhibition were pre-exposed to physiological (5mM) or excess (11mM) glucose for 4 to 24 hrs. Basal insulin secretion, respiration and metabolites were measured. Pre-exposure to excess glucose resulted in sustained mTORC1 hyperactivation, basal insulin secretion, higher basal respiration and increased maximal respiratory capacity, due to accelerated mitochondrial pyruvate metabolism. Inhibition of mTORC1 reduced basal insulin secretion, basal respiration and maximal respiratory capacity. Moreover, cells challenged with excess glucose had increased levels of glycolysis and TCA cycle intermediates. Our results suggest that hyperactivation of mTORC1 induced by excess glucose results in increased energy demand and in the generation of metabolic factors that can lead to basal insulin hypersecretion. Therefore, targeting mitochondrial pyruvate metabolism and /or mTORC1 signaling could potentially lead to specific therapies to control hyperinsulinemia and diabetes progression.

Nutrition

Glucose

Hyperinsulinemia

Insulin secretion

mTORC1

Respiration

Type 2 diabetes

LKB1-AMPK-SIK2-CRTC2 Pathway in Beta Cells

Fu, Accalia

January 2013

In 2011, Diabetes and prediabetes affected 9 million Canadians and 366 million people worldwide (Canadian Diabetes Website). The underlying pathophysiology of diabetes is beta cell dysfunction leading to loss of appropriate insulin secretion and resulting in hyperglycemia. I have focused on identifying critical molecular regulators of beta cell function and insulin secretion. The CRTC2-CREB pathway is required for maintaining beta cell mass and insulin secretion. I propose that identifying kinases that regulate CRTC-CREB activity will identify other important regulators of pancreatic beta cell survival and function. First, I have identified several AMP kinases as inhibitors of CRTC2-CREB that are activated by an upstream kinase, LKB1. I then went on to generate mice with a beta cell-specific deletion of LKB1 during adulthood. Loss of LKB1 increased insulin secretion and glucose clearance through enhanced beta cell mass and proliferation. The increased insulin secretion was largely the result of loss of AMPK activity and consequent constitutive mTor activity. AMPK is activated under starvation conditions and as such is thought to be a critical regulator of beta cell function. However, the decrease of AMPK activity in high glucose has been a strong argument against it being a critical effector of insulin secretion. I provide genetic evidence supporting the idea that AMPK activity attenuates insulin secretion. During periods of starvation where AMPK activity is high there is a chronic dampening effect on events that prepare beta cells for the next round of insulin secretion. Surprisingly, another downstream kinase of LKB1, SIK2, has opposing functions in the beta cell. I present evidence that the LKB1-AMPK axis attenuates beta cell functions and that targeting this pathway in beta cells may be of therapeutic benefit for T2D.

pancreatic beta cells

LKB1

AMPK

insulin secretion

islets

diabetes

Role of mitochondrial dysfunction in the development of nutrient-induced hyperinsulinemia

Alsabeeh, Nour

12 June 2018

Pancreatic beta cells sense fluctuations in circulating nutrients and adjust the rate of insulin secretion to maintain glucose homeostasis. Mitochondria integrate changes in nutrient flux to the generation of signals that modulate insulin secretion via oxidative phosphorylation. Type 2 Diabetes (T2D) is characterized by beta cell mitochondrial dysfunction and impairment of insulin secretion. Early stage progression of this disease in obese and pre-diabetic subjects is characterized by basal hypersecretion of insulin and increased insulin resistance in peripheral tissues including muscle, liver and adipose tissue. Whether basal hypersecretion of insulin or insulin resistance is the primary defect in T2D progression is still debated. The molecular mechanism underlying basal insulin hypersecretion and how it may lead to beta cell failure are not understood. Herein, we optimize a model of glucolipotoxicity that results in increased basal and reduced stimulated insulin secretion response. Furthermore, we show that pancreatic islets exposed to excess nutrients in vitro or isolated from high fat diet fed animals, have a decreased bioenergetic efficiency, which is characterized by increased mitochondrial proton leak. Leak represents the fraction of oxygen consumed that is not coupled to ATP production. We show that leak is sufficient to induce insulin secretion at basal glucose levels and that nutrient-induced insulin secretion at basal glucose is leak-dependent. Finally, we identify the mitochondrial permeability transition pore (PTP) as the source of the leak. Our findings suggest the PTP may be a potential therapeutic target to prevent/delay the onset of hyperinsulinemia in pre-diabetic subjects.

Physiology

Cyclophilin D

Diabetes

Insulin secretion

Islet

Mitochondria

Proton leak

Studies on pathophysiological significance of intraislet ghrelin using transgenic animal model. / 遺伝子改変動物を用いた膵島由来グレリンの病態生理学的意義の検討

Bando, Mika

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第18197号 / 人健博第14号 / 新制||人健||2(附属図書館) / 31055 / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 藤井 康友, 教授 岡 昌吾, 教授 横出 正之 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM

ghrelin

insulin secretion

glucose metabolism

diabetes

beta cell proliferation

498

Leptin restores the insulinotropic effect of exenatide in a mouse model of type 2 diabetes with increased adiposity induced by streptozotocin and high-fat diet / レプチンはストレプトゾトシンおよび高脂肪食負荷により誘導した脂肪蓄積の増加した2型糖尿病モデルマウスにおいてエキセナチドのインスリン分泌促進作用を回復させる

Sakai, Takeru

23 January 2015

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第18683号 / 医博第3955号 / 新制||医||1007(附属図書館) / 31616 / 京都大学大学院医学研究科医学専攻 / (主査)教授 横出 正之, 教授 岩田 想, 教授 川口 義弥 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DGAM

Leptin

Exenatide

Drug therapy

Combination

Adiposity

Insulin secretion

490

The effect of simvastatin and pitavastatin on insulin secretion from clonal pancreatic ß-cells (INS-1)

Abdul-Akbar, Princess Maryam

13 February 2024

OBJECTIVE: The 10th leading cause of death in the United States is heart disease. Most of the deaths by heart disease has a correlation with an occlusion of the coronary arteries. While diabetes mellitus is currently the 7th leading cause of death, which is a chronic condition that affects more than 37 million people in America. The global epidemic of obesity largely explains the dramatic increase in the incidence and prevalence of type 2 diabetes (T2D) over the past 25 years. Statins are well known drugs to decrease LDL for individuals who suffer from hypercholesterinemia; however, there is also an increased risk of developing diabetes mellitus. An estimation of 10-20 per 10,000 patients per year demonstrated an excess risk of T2D with the long-term use of statin. Here we examine the effects of simvastatin and pitavastatin on pancreatic ß-cell function to determine whether altered insulin secretion may contribute to an increased risk of T2D. METHODS: The experiments were performed using clonal pancreatic ß-cells (INS-1). The cells were grown in 4 mM glucose in RPMI media. Cells were grown for three days before adding the different types of statins: simvastatin and pitavastatin for one day. Then the cells were used to perform the glucose-induced insulin secretion (GSIS) experiment. Insulin secretion and insulin content were assay using a fluorescence-based immunoassay. The study was calculated using Microsoft Excel. Standard variance and standard error were used to assess the difference sets of data. RESULTS: INS-1 cells responded to acute glucose stimulation after chronic culture in both low (4 mM) and high (11 mM) glucose. Secretion from cells cultured at 4 mM glucose was higher than cells cultured at 11 mM glucose at all glucose concentrations tested, characteristic of the effects of glucolipotoxicity (GLT). Insulin content in cells cultured at high glucose was decreased 8.6-fold compared to cells cultured at the more physiological low glucose condition. When normalized to basal secretion cells cultured at high glucose exhibited basal hypersecretion and increased GSIS compared to those in low glucose. Simvastatin (100 nM, 24 hrs) increased basal insulin secretion to a greater extent than Pitavastatin. The effects of pitavastatin on basal insulin secretion were less consistent than seen with simvastatin. Simvastatin was also shown to inhibit GSIS from cells cultured at 4 mM glucose, while pitavastatin increased GSIS. CONCLUSION: Both pitavastatin and simvastatin alter insulin secretion from pancreatic ß-cells. The effect of simvastatin to both increase basal and decrease GSIS, characteristic of GLT suggests pitavastatin may be the statin of choice to reduce the risk of statin-induced T2D.

Medicine

Glucolipotoxicity

Hyperinsulinemia

Insulin secretion

LDL

Statins

Type 2 Diabetes

Differential Role of CEACAM Proteins in Regulating Insulin Metabolism

Dai, Tong

January 2005

No description available.

Health Sciences, Pharmacology

Insulin Resistance

Insulin Secretion

Lipid Metabolism

Role of Na+K+2Cl¿¿¿¿¿¿ Co-transporters in Insulin Secretion

Alshahrani, Saeed

17 September 2012

No description available.

Pharmacology

&946

-cell, Insulin Secretion, NKCC1, NKCC2

The anti-diabetic mechanisms by isoflavone genistein

Fu, Zhuo

10 June 2011

Diabetes is growing public health problem in the United States. Both in Type 1 and Type 2 diabetes, the deterioration of glycemic control over time is largely due to insulin secretory dysfunction and significant loss of functional β-cells. As such, the search for novel agents that promote β-cell survival and preserve functional β-cell mass are one of the essential strategies to prevent and treat the onset of diabetes. Genistein, a flavonoid in legumes and some herbal medicines, has various biological actions. It was recently shown that dietary intake of foods containing genistein improves diabetes in both experimental animals and humans. However, the potential anti-diabetic mechanisms of genistein are unclear. In the present study, we first investigated the effect of genistein on β-cell insulin secretion and proliferation and cellular signaling related to these effects in vitro and in vivo. We then determined its anti-diabetic potential in insulin-deficient and obese diabetic mouse models. The results in our study showed that exposure of clonal insulin secreting (INS1E) cells or isolated pancreatic islets to genistein at physiologically relevant concentrations (1-10 μM) enhanced glucose-stimulated insulin secretion (GSIS), whereas insulin content was not altered, suggesting that genistein-enhanced GSIS is not due to a modulation of insulin synthesis. This genistein's effect is protein tyrosine kinase- and KATP channel-independent. In addition, genistein had no effect on glucose transporter-2 expression or cellular ATP production, but similarly augmented pyruvate-stimulated insulin secretion in INS1E cells, indicating that genistein improvement of insulin secretion in β-cells is not related to an alternation in glucose uptake or the glycolytic pathway. Further, genistein (1-10 μM) induced both INS1 and human islet β-cell proliferation following 24 h of incubation, with 5 μM genistein inducing a maximal 27% increase. The effect of genistein on β-cell proliferation was neither dependent on estrogen receptors, nor shared by 17β-estradiol or a host of structurally related flavonoid compounds. Pharmacological or molecular intervention of PKA or ERK1/2 completely abolished genistein-stimulated β-cell proliferation, suggesting that both molecules are essential for genistein action. Consistent with its effect on cell proliferation, genistein induced cAMP/PKA signaling and subsequent phosphorylation of ERK1/2 in both INS1 cells and human islets. Furthermore, genistein induced protein expression of cyclin D1, a major cell-cycle regulator essential for β-cell growth. Dietary intake of genistein significantly improved hyperglycemia, glucose tolerance, and blood insulin levels in both insulin deficient type 1 and obese type 2 diabetic mice, concomitant with improved islet β-cell proliferation, survival, and mass. These changes were not due to alternations in animal body weight gain, food intake, fat deposit, plasma lipid profile, or peripheral insulin sensitivity. Collectively, these findings provide better understanding of the mechanism underlying the anti-diabetic effects of genistein. Loss of functional β-cell mass through apoptosis is central to the development of both T1D and T2D and islet β-cell preservation and regeneration are very important components of β-cell adaptation to increased apoptosis and insulin resistance and therefore holds promise as a treatment for this disease. In this context, these findings may potentially lead to the development of novel low-cost natural agents for prevention and treatment of diabetes. / Ph. D.

Apoptosis

proliferation

insulin secretion

β-cell

diabetes

genistein

The Art of Modeling and Simulation of Multiscale Biochemical Systems

Pu, Yang

14 May 2015

In this thesis we study modeling and simulation approaches for multiscale biochemical systems. The thesis addresses both modeling methods and simulation strategies. In the first part, we propose modeling methods to study the behavior of the insulin secretion pathway. We first expand the single cell model proposed by Bertram et. al. to model multiple cells. Synchronization among multiple cells is observed. Then an unhealthy cell model is proposed to study the insulin secretion failure caused by weakening of mitochondria function. By studying the interaction between the healthy and unhealthy cells, we find that the insulin secretion can be reinstated by increasing the glucokinase level. This new discovery sheds light on antidiabetic medication. In order to study the stochastic dynamics of the insulin secretion pathway, we first apply the hybrid method to model the discrete events in the insulin secretion pathway. Based on the hybrid model, a probability based measurement is proposed and applied to test the new antidiabetic remedy. In the second part, we focus on different simulation schemes for multiscale biochemical systems. We first propose a partitioning strategy for the hybrid method which leads to an efficient way of building stochastic cell cycle models. Then different implementation methods for the hybrid method are studied. A root finding method based on inverse interpolation is introduced to implement the hybrid method with three different ODE solvers. A detailed discussion of the performance of these three ODE solvers is presented. Last, we propose a new strategy to automatically detect stiffness and identify species that cause stiffness for the Tau-Leaping method, as well as two stiffness reduction methods. The efficiency is demonstrated by applying this new strategy on a stiff decaying dimerization model and a heat shock protein regulation model. / Ph. D.

Insulin secretion pathway

Numerical model

Hybrid method

SSA

QSSA