β-Cell–Derived Angiopoietin-1 Regulates Insulin Secretion and Glucose Homeostasis by Stabilizing the Islet Microenvironment

Park, Ho Seon; Kim, Hak Zoo; Park, Jong Suk; Lee, Junyeop; Lee, Seung–Pyo; Kim, Hail; Ahn, Chul Woo; Nakaoka, Yoshikazu; Koh, Gou Young; Kang, Shinae

doi:10.2337/db18-0864

Cited by 9 publications

(10 citation statements)

References 51 publications

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“…Pancreatic islets are endocrine mini-organs rich in blood vessels ( 1 , 2 ). Close interactions between islet endocrine cells and vascular cells are established early on during development and maintained throughout life, by providing mutual trophic and functional support ( 2 – 7 ). Indeed, as any other endocrine organ, islets depend on their blood vessels to function properly ( 8 ).…”

Section: Introductionmentioning

confidence: 99%

Functional Characterization of the Human Islet Microvasculature Using Living Pancreas Slices

Gonçalves

Almaça

2021

Front. Endocrinol.

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Pancreatic islets are clusters of endocrine cells that secrete different hormones to regulate blood glucose levels. Efficient hormone secretion requires a close interaction of endocrine cells with their vascular system. Islets receive blood through feeding arteriole(s) that branch into capillaries made of endothelial cells covered by pericytes. While a lot is known about rodent islet blood vessels, the structure and function of the human islet microvasculature has been less investigated. In this study, we used living pancreas slices from non-diabetic human donors to examine the function of human islet blood vessels. Living human pancreas slices were incubated with a membrane permeant calcium indicator and pericytes/smooth muscle cells were visualized with a fluorescent antibody against the mural cell marker NG2 proteoglycan. By confocal microscopy, we simultaneously recorded changes in the diameter of lectin-labeled blood vessels and cytosolic calcium levels in mural cells in islets. We tested several stimuli with vasoactive properties, such as norepinephrine, endothelin-1 and adenosine and compared human vascular responses with those previously published for mouse islet blood vessels. Norepinephrine and endothelin-1 significantly constricted human islet feeding arterioles, while adenosine dilated them. Islet capillaries were less responsive and only 15–20% of the mouse and human islet capillary network showed vasomotion. Nevertheless, in these responsive regions, norepinephrine and endothelin-1 decreased both mouse and human islet capillary diameter. Changes in islet blood vessel diameter were coupled to changes in cytosolic calcium levels in adjacent mouse and human islet mural cells. Our study shows that mural cells in islets are the targets of different regulatory mechanisms of islet blood perfusion. Several alterations of the human islet microvasculature occur during diabetes progression. Elucidating their functional consequences in future studies will be critical for our understanding of disease pathogenesis.

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Section: Introductionmentioning

confidence: 99%

Functional Characterization of the Human Islet Microvasculature Using Living Pancreas Slices

Gonçalves

Almaça

2021

Front. Endocrinol.

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“… 39 Meanwhile, a defect in ß-cell-derived Ang1 induced islet inflammation, disrupted the normal intraislet vascular ultrastructure and impaired the insulin secretory mechanism in response to a high fat diet. 40 Although the mouse high fat diet model differs from human patients with respect to the development of T2DM, these reports nonetheless indicate that the balance of Ang1 and Ang2 governs the microenvironment and function of islets under metabolic challenge. Importantly, the dysregulation of the secretion of Ang1/2 equilibrium by either decreased Ang1 or increased Ang2 levels has been clinically associated with T2DM and vascular dysfunction, 9 41 underscoring the question of whether altered Ang1-Tie2 signaling contributes to impaired pancreatic islet vasculature, homeostasis and diabetes progression.…”

Section: Discussionmentioning

confidence: 99%

Systemic AAV10.COMP-Ang1 rescues renal glomeruli and pancreatic islets in type 2 diabetic mice

Tian

Carroll

Tang

et al. 2020

BMJ Open Diab Res Care

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IntroductionDiabetic hyperglycemia causes progressive and generalized damage to the microvasculature. In renal glomeruli, this results in the loss of podocytes with consequent loss of constitutive angiopoietin-1 (Ang1) signaling, which is required for stability of the glomerular endothelium. Repeated tail vein injection of adenovirus expressing COMP-Ang1 (a stable bioengineered form of Ang1) was previously reported to improve diabetic glomerular damage despite the liver and lungs being primary targets of adenoviral infection. We thus hypothesized that localizing delivery of sustained COMP-Ang1 to the kidney could increase its therapeutic efficacy and safety for the treatment of diabetes.Research design and methodsUsing AAVrh10 adeno-associated viral capsid with enhanced kidney tropism, we treated 10-week-old uninephrectomized db/db mice (a model of type 2 diabetes) with a single dose of AAVrh10.COMP-Ang1 delivered via the intracarotid artery, compared with untreated diabetic db/db control and non-diabetic db/m mice.ResultsSurprisingly, both glomerular and pancreatic capillaries expressed COMP-Ang1, compensating for diabetes-induced loss of tissue Ang1. Importantly, treatment with AAVrh10.COMP-Ang1 yielded a significant reduction of glycemia (blood glucose, 241±193 mg/dL vs 576±31 mg/dL; glycosylated hemoglobin, 7.2±1.5% vs 11.3±1.3%) and slowed the progression of albuminuria and glomerulosclerosis in db/db mice by 70% and 61%, respectively, compared with untreated diabetic db/db mice. Furthermore, COMP-Ang1 ameliorated diabetes-induced increases of NF-kBp65, nicotinamide adenine dinucleotide phosphate (NAPDH) oxidase-2 (Nox2), p47phox and productions of myeloperoxidase, the inflammatory markers in both renal and pancreatic tissues, and improved beta-cell density in pancreatic islets.ConclusionsThese results highlight the potential of localized Ang1 therapy for treatment of diabetic visceropathies and provide a mechanistic explanation for reported improvements in glucose control via Ang1/Tie2 signaling in the pancreas.

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“…In the pancreas, insulin resistance by HFD induces dilation of pancreatic islet vasculature, rather than angiogenesis, and islet endothelial dysfunction may be associated with reduced insulin release in isolated islets . Interestingly a potent angiogenic factor released by pancreatic beta‐cells did not increase vascular density but maintains endothelial cell ultrastructure . This stabilizes the blood vessels in the islet, regulating islet morphology, insulin secretion, and therefore glucose homeostasis .…”

Section: Liver and Pancreasmentioning

confidence: 97%

“…82 Interestingly a potent angiogenic factor released by pancreatic beta-cells did not increase vascular density but maintains endothelial cell ultrastructure. 83 This stabilizes the blood vessels in the islet, regulating islet morphology, insulin secretion, and therefore glucose homeostasis. 83,84 Plasma hyperinsulinaemia is a combination of the release of insulin by the pancreas, and clearance, primarily by the liver, yet these two tissues are also exposed to the hyperinsulinaemia they induce, which can affect their function.…”

Section: Liver and Pan Cre A Smentioning

confidence: 99%

“…83 This stabilizes the blood vessels in the islet, regulating islet morphology, insulin secretion, and therefore glucose homeostasis. 83,84 Plasma hyperinsulinaemia is a combination of the release of insulin by the pancreas, and clearance, primarily by the liver, yet these two tissues are also exposed to the hyperinsulinaemia they induce, which can affect their function. The relationship between hyperinsulinaemia and the endothelial function is not clear.…”

Section: Liver and Pan Cre A Smentioning

confidence: 99%

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The vascular endothelium plays a role in insulin action

Kolka

2019

Clin Exp Pharma Physio

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The endocrine system relies on the vasculature for delivery of hormones throughout the body, and the capillary microvasculature is the site where the hormones cross from the blood into the target tissue. Once considered an inert wall, various studies have now highlighted the functions of the capillary endothelium to regulate transport and therefore affect or maintain the interstitial environment. The role of the capillary may be clear in areas where there is a continuous endothelium, yet there also appears to be a role of endothelial cells in tissues with a sinusoidal structure. Here we focused on the most common endocrine disorder, diabetes, and several of the target organs associated with the disease, including skeletal muscle, liver and pancreas. However, it is important to note that the ability of hormones to cross the endothelium to reach their target tissue is a component of all endocrine functions. It is also a consideration in organs throughout the body and may have greater impact for larger hormones with target tissues containing a continuous endothelium. We noted that the blood levels do not always equal interstitial levels, which is what the cells are exposed to, and discussed how this may change in diseases such as obesity and insulin resistance. The capillary endothelium is, therefore, an essential and understudied aspect of endocrinology and metabolism that can be altered in disease, which may be an appropriate target for treatment.

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β-Cell–Derived Angiopoietin-1 Regulates Insulin Secretion and Glucose Homeostasis by Stabilizing the Islet Microenvironment

Cited by 9 publications

References 51 publications

Functional Characterization of the Human Islet Microvasculature Using Living Pancreas Slices

Functional Characterization of the Human Islet Microvasculature Using Living Pancreas Slices

Systemic AAV10.COMP-Ang1 rescues renal glomeruli and pancreatic islets in type 2 diabetic mice

The vascular endothelium plays a role in insulin action

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