The role of impaired glucagon secretion in life-threatening hypoglycaemia of type 1 diabetes: mechanism and therapeutic potential
Lead Research Organisation:
University of Oxford
Department Name: RDM OCDEM
Abstract
The pancreatic islets play a central role in the regulation of blood glucose. They do so, by secreting the two hormones insulin (glucose-lowering) and glucagon (glucose-increasing).
Type-1 diabetes (T1D) is caused by an autoimmune attack killing the insulin-secreting beta-cells but the other islet cells (including the glucagon-producing alpha-cells) remain. Our understanding of the acute and longterm impact of T1D on the alpha-cells is sketchy but it is clear that defects in the release exacerbate the impact of the insulin deficiency and make T1D more difficult to treat.
In type-1 diabetes (T1D), the loss of endogenous insulin production must be treated with insulin injections. However, insulin must be carefully dosed so that a fall in blood glucose below the normal range (hypoglycaemia) does not occur. Normally, a fall in blood glucose triggers strong stimulation of glucagon release but this mechanism ('counter-regulation') is faulty in many people with T1D. This increases the risk of severe hypoglycaemia and may result in coma and death. It has been estimated that one in ten T1D patients die of hypoglycaemia. Hypoglycaemia is also a problem in insulin-treated patients with type 2 diabetes (T2D). In fact, because 90% of all diabetic patients have T2D (>400 million worldwide), hypoglycaemia affect a far greater number of patients with T2D than with T1D. Once hypoglycaemia has occurred, the risk of experiencing another hypoglycaemic episode is dramatically increased. The underlying mechanisms are not known.
Our preliminary data suggest that the loss of counter-regulatory glucagon secretion is caused by a 'glucose blindness' of the glucagon-releasing alpha-cells. We will now determine how and when this defect develops during the onset and progression of T1D and whether it can be corrected by medicines, some of which are already used to treat patients with T2D.
Our laboratory pioneered the characterisation of the islet alpha-cells: first using mouse islets and subsequently in human islets (from the Oxford Clinical Islet Isolation and Transplantation Centre). However, access to human pancreatic islets from donors with T1D is very limited (they are not used for transplantation) and for some of pilot studies we will also use a well-established and widely used model of human T1D (the NOD mouse). There have been no functional studies of glucagon secretion in NOD mice. Our preliminary studies suggest that they faithfully recapitulate the glucagon secretion defects seen clinically in patients with T1D.
The ultimate goal of this project is to prevent (or reduce the risk of) hypoglycaemia. This would enable more aggressive insulin therapy to achieve better glucose control with resultant reduction of secondary complications (heart and kidney failure, blindness etc.).
Type-1 diabetes (T1D) is caused by an autoimmune attack killing the insulin-secreting beta-cells but the other islet cells (including the glucagon-producing alpha-cells) remain. Our understanding of the acute and longterm impact of T1D on the alpha-cells is sketchy but it is clear that defects in the release exacerbate the impact of the insulin deficiency and make T1D more difficult to treat.
In type-1 diabetes (T1D), the loss of endogenous insulin production must be treated with insulin injections. However, insulin must be carefully dosed so that a fall in blood glucose below the normal range (hypoglycaemia) does not occur. Normally, a fall in blood glucose triggers strong stimulation of glucagon release but this mechanism ('counter-regulation') is faulty in many people with T1D. This increases the risk of severe hypoglycaemia and may result in coma and death. It has been estimated that one in ten T1D patients die of hypoglycaemia. Hypoglycaemia is also a problem in insulin-treated patients with type 2 diabetes (T2D). In fact, because 90% of all diabetic patients have T2D (>400 million worldwide), hypoglycaemia affect a far greater number of patients with T2D than with T1D. Once hypoglycaemia has occurred, the risk of experiencing another hypoglycaemic episode is dramatically increased. The underlying mechanisms are not known.
Our preliminary data suggest that the loss of counter-regulatory glucagon secretion is caused by a 'glucose blindness' of the glucagon-releasing alpha-cells. We will now determine how and when this defect develops during the onset and progression of T1D and whether it can be corrected by medicines, some of which are already used to treat patients with T2D.
Our laboratory pioneered the characterisation of the islet alpha-cells: first using mouse islets and subsequently in human islets (from the Oxford Clinical Islet Isolation and Transplantation Centre). However, access to human pancreatic islets from donors with T1D is very limited (they are not used for transplantation) and for some of pilot studies we will also use a well-established and widely used model of human T1D (the NOD mouse). There have been no functional studies of glucagon secretion in NOD mice. Our preliminary studies suggest that they faithfully recapitulate the glucagon secretion defects seen clinically in patients with T1D.
The ultimate goal of this project is to prevent (or reduce the risk of) hypoglycaemia. This would enable more aggressive insulin therapy to achieve better glucose control with resultant reduction of secondary complications (heart and kidney failure, blindness etc.).
Technical Summary
Glucagon is the body's principal hyperglycaemic hormone and acts by stimulating hepatic glucose production. It is released from the alpha-cells of the pancreatic islets in response to neurotransmitters (like adrenaline) and a fall in plasma glucose below the normal 5mM but inhibited by somatostatin (released from neighbouring delta-cells).
Type-1 diabetes (T1D) is a bihormonal disorder involving (nearly) complete loss of insulin secretion. Crucially, in T1D glucagon secretion in response to hypoglycemia also becomes defective. This increases the risk of severe hypoglycaemia, a potentially fatal complication of insulin therapy. Hypoglycaemia accounts for 10% of the mortality in patients with T1D. The only effective treatment (apart from reducing insulin) is islet or pancreas transplantation but the requirement for immunosuppression makes this a last resort.
We will explore the mechanisms underlying the defective glucagon secretion in T1D using in vivo (insulin tolerance tests) and ex vio techniques (hormone secretion, electrophysiology, imaging, gene expression analysis). For our experiment we will use the NOD mouse model, which previously has been widely used for studies of autoimmune destruction of the beta-cells but with little attention being paid to the alpha- and delta-cells that survive the autoimmune attack.
Preliminary data indicate that NOD mice recapitulate the loss of hypoglycaemia-induced glucagon secretion seen in patients wit. We will explore how the autoimmune attack, and/or the subsequent reorganisation of the islet and resultant hyperglycaemia results in dysregulated glucagon secretion.
The proposed studies will result in new therapeutic paradigms that reduce the risk of hypoglycaemia, thereby enabling more aggressive insulin therapy that reduce the risk of secondary microvascular complications (including heart/renal failure).
Type-1 diabetes (T1D) is a bihormonal disorder involving (nearly) complete loss of insulin secretion. Crucially, in T1D glucagon secretion in response to hypoglycemia also becomes defective. This increases the risk of severe hypoglycaemia, a potentially fatal complication of insulin therapy. Hypoglycaemia accounts for 10% of the mortality in patients with T1D. The only effective treatment (apart from reducing insulin) is islet or pancreas transplantation but the requirement for immunosuppression makes this a last resort.
We will explore the mechanisms underlying the defective glucagon secretion in T1D using in vivo (insulin tolerance tests) and ex vio techniques (hormone secretion, electrophysiology, imaging, gene expression analysis). For our experiment we will use the NOD mouse model, which previously has been widely used for studies of autoimmune destruction of the beta-cells but with little attention being paid to the alpha- and delta-cells that survive the autoimmune attack.
Preliminary data indicate that NOD mice recapitulate the loss of hypoglycaemia-induced glucagon secretion seen in patients wit. We will explore how the autoimmune attack, and/or the subsequent reorganisation of the islet and resultant hyperglycaemia results in dysregulated glucagon secretion.
The proposed studies will result in new therapeutic paradigms that reduce the risk of hypoglycaemia, thereby enabling more aggressive insulin therapy that reduce the risk of secondary microvascular complications (including heart/renal failure).
Publications
Armour SL
(2023)
Glucose Controls Glucagon Secretion by Regulating Fatty Acid Oxidation in Pancreatic a-Cells.
in Diabetes
Dai XQ
(2022)
Heterogenous impairment of a cell function in type 2 diabetes is linked to cell maturation state.
in Cell metabolism
Gandasi N
(2023)
GLP-1 metabolite GLP-1(9-36) is a systemic inhibitor of mouse and human pancreatic islet glucagon secretion
in Diabetologia
Gloyn AL
(2022)
Every islet matters: improving the impact of human islet research.
in Nature metabolism
Hatamie A
(2021)
Nanoscale Amperometry Reveals that Only a Fraction of Vesicular Serotonin Content is Released During Exocytosis from Beta Cells
in Angewandte Chemie
Haythorne E
(2022)
Altered glycolysis triggers impaired mitochondrial metabolism and mTORC1 activation in diabetic ß-cells.
in Nature communications
MacDonald PE
(2023)
Metabolic Messengers: glucagon.
in Nature metabolism
Spiliotis II
(2022)
Reducing hyperglucagonaemia in type 2 diabetes using low-dose glibenclamide: Results of the LEGEND-A pilot study.
in Diabetes, obesity & metabolism
Veprik A
(2022)
Acetyl-CoA-carboxylase 1 (ACC1) plays a critical role in glucagon secretion.
in Communications biology
Description | Alpha cell function in people with type 1 diabetes with and without severe hypoglycemia |
Amount | $1,275,000 (USD) |
Funding ID | G-2305-06047 |
Organisation | The Leona M. and Harry B. Helmsley Charitable Trust |
Sector | Charity/Non Profit |
Country | United States |
Start | 09/2022 |
End | 09/2025 |
Description | Generation of alpha-cells from patients with type-1 diabetes with or without recurrent hypoglycaemia |
Organisation | Mayo Clinic |
Country | United States |
Sector | Charity/Non Profit |
PI Contribution | We will provide cell samples from patients with/without recurrent hypoglycaemia, generate induced pluripotent stem cells (iPSC), generate iPSC-derived alpha-cells and conduct a detailed functional characterization of these cells |
Collaborator Contribution | Dr Quinn Peterson is an expert in iPSC work and we have previousl;y collaborated with him on human alpha-cells derived from iPSCs. We will now generate alpha-cells from people with type-1 diabetes with or without recurrent hypoglycaemia to document any alpha-cell defects that may predispose to this problem |
Impact | Peterson, Q.P., A. Veres, L. Chen, M.Q. Slama, J.H.R. Kenty, S. Hassoun, M.R. Brown, H. Dou, C.D. Duffy, Q. Zhou, A.V. Matveyenko, B. Tyrberg, M. Sorhede-Winzell, P. Rorsman, and D.A. Melton, A method for the generation of human stem cell-derived alpha cells. Nat Commun, 2020. 11(1): p. 2241. |
Start Year | 2021 |