Insulin granule biogenesis and exocytosis

Omar‐Hmeadi, Muhmmad; Idevall‐Hagren, Olof

doi:10.1007/s00018-020-03688-4

Cited by 74 publications

(67 citation statements)

References 165 publications

(198 reference statements)

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“…Insulin is stored in a Zn 2+ -stabilized hexameric state in secretory granules that form at the Golgi. These granules undergo fusion with the plasma membrane (or ‘exocytosis’) primarily in response to a rise in the level of glucose in the blood [ 24 , 25 ] (summarized in figure 1 ). Glucose-stimulated insulin secretion occurs as a result of changes in metabolism and ion fluxes in the β-cells.…”

Section: Insulin Secretionmentioning

confidence: 99%

“…Decreased efflux of K + from the β-cells contributes to membrane depolarization and the opening of voltage-gated Ca 2+ channels, the activity of which is also controlled by other ion fluxes controlling membrane potential. The resulting Ca 2+ influx stimulates SNARE protein-dependent fusion of insulin granules with the plasma membrane and secretion of insulin from the β-cell [ 25 ]. Insulin secretion occurs in two phases: the first phase has been proposed to occur due to the rapid exocytosis of a ‘readily-releasable’ pool of granules, whereas the second-phase insulin secretion may reflect the recruitment of ‘newcomer’ granules to the membrane and their subsequent exocytosis [ 25 ].…”

Section: Insulin Secretionmentioning

confidence: 99%

“…The resulting Ca 2+ influx stimulates SNARE protein-dependent fusion of insulin granules with the plasma membrane and secretion of insulin from the β-cell [ 25 ]. Insulin secretion occurs in two phases: the first phase has been proposed to occur due to the rapid exocytosis of a ‘readily-releasable’ pool of granules, whereas the second-phase insulin secretion may reflect the recruitment of ‘newcomer’ granules to the membrane and their subsequent exocytosis [ 25 ]. Several SNARE proteins are involved in insulin granule exocytosis including syntaxin 1 and SNAP25 (plasma membrane SNAREs), and vesicle-associated membrane protein-2 (VAMP-2) on the insulin granule membrane [ 25 ].…”

Section: Insulin Secretionmentioning

confidence: 99%

“…Insulin secretion occurs in two phases: the first phase has been proposed to occur due to the rapid exocytosis of a ‘readily-releasable’ pool of granules, whereas the second-phase insulin secretion may reflect the recruitment of ‘newcomer’ granules to the membrane and their subsequent exocytosis [ 25 ]. Several SNARE proteins are involved in insulin granule exocytosis including syntaxin 1 and SNAP25 (plasma membrane SNAREs), and vesicle-associated membrane protein-2 (VAMP-2) on the insulin granule membrane [ 25 ]. Additional SNAREs appear to function in granule exocytosis that contributes to second-phase insulin secretion, including syntaxin-3/-4 and VAMP8 [ 25 ].…”

Section: Insulin Secretionmentioning

confidence: 99%

“…Several SNARE proteins are involved in insulin granule exocytosis including syntaxin 1 and SNAP25 (plasma membrane SNAREs), and vesicle-associated membrane protein-2 (VAMP-2) on the insulin granule membrane [ 25 ]. Additional SNAREs appear to function in granule exocytosis that contributes to second-phase insulin secretion, including syntaxin-3/-4 and VAMP8 [ 25 ]. Calcium-secretion coupling involves members of the synaptotagmin protein family, in particular synaptotagmin-7 [ 26 ] and synaptotagmin-9 [ 25 , 27 , 28 ].…”

Section: Insulin Secretionmentioning

confidence: 99%

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Regulatory effects of protein S-acylation on insulin secretion and insulin action

2021

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Post-translational modifications (PTMs) such as phosphorylation and ubiquitination are well-studied events with a recognized importance in all aspects of cellular function. By contrast, protein S-acylation, although a widespread PTM with important functions in most physiological systems, has received far less attention. Perturbations in S-acylation are linked to various disorders, including intellectual disability, cancer and diabetes, suggesting that this less-studied modification is likely to be of considerable biological importance. As an exemplar, in this review, we focus on the newly emerging links between S-acylation and the hormone insulin. Specifically, we examine how S-acylation regulates key components of the insulin secretion and insulin response pathways. The proteins discussed highlight the diverse array of proteins that are modified by S-acylation, including channels, transporters, receptors and trafficking proteins and also illustrate the diverse effects that S-acylation has on these proteins, from membrane binding and micro-localization to regulation of protein sorting and protein interactions.

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Section: Insulin Secretionmentioning

confidence: 99%

Section: Insulin Secretionmentioning

confidence: 99%

Section: Insulin Secretionmentioning

confidence: 99%

Section: Insulin Secretionmentioning

confidence: 99%

Section: Insulin Secretionmentioning

confidence: 99%

See 3 more Smart Citations

Regulatory effects of protein S-acylation on insulin secretion and insulin action

2021

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Condensation of the β‐cell secretory granule luminal cargoes pro/insulin and ICA512 RESP18 homology domain

et al. 2023

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ICA512/PTPRN is a receptor tyrosine‐like phosphatase implicated in the biogenesis and turnover of the insulin secretory granules (SGs) in pancreatic islet beta cells. Previously we found biophysical evidence that its luminal RESP18 homology domain (RESP18HD) forms a biomolecular condensate and interacts with insulin in vitro at close‐to‐neutral pH, that is, in conditions resembling those present in the early secretory pathway. Here we provide further evidence for the relevance of these findings by showing that at pH 6.8 RESP18HD interacts also with proinsulin—the physiological insulin precursor found in the early secretory pathway and the major luminal cargo of β‐cell nascent SGs. Our light scattering analyses indicate that RESP18HD and proinsulin, but also insulin, populate nanocondensates ranging in size from 15 to 300 nm and 10e2 to 10e6 molecules. Co‐condensation of RESP18HD with proinsulin/insulin transforms the initial nanocondensates into microcondensates (size >1 μm). The intrinsic tendency of proinsulin to self‐condensate implies that, in the ER, a chaperoning mechanism must arrest its spontaneous intermolecular condensation to allow for proper intramolecular folding. These data further suggest that proinsulin is an early driver of insulin SG biogenesis, in a process in which its co‐condensation with RESP18HD participates in their phase separation from other secretory proteins in transit through the same compartments but destined to other routes. Through the cytosolic tail of ICA512, proinsulin co‐condensation with RESP18HD may further orchestrate the recruitment of cytosolic factors involved in membrane budding and fission of transport vesicles and nascent SGs.

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Sunlight‐Controllable Biopharmaceutical Production for Remote Emergency Supply of Directly Injectable Therapeutic Proteins

Stefanov

Mansouri

Hamri

et al. 2022

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Biopharmaceutical manufacturing requires specialized facilities and a long‐range cold supply chain for the delivery of the therapeutics to patients. In order to produce biopharmaceuticals in locations lacking such infrastructure, a production process is designed that utilizes the trigger‐inducible release of large quantities of a stored therapeutic protein from engineered endocrine cells within minutes to generate a directly injectable saline solution of the protein. To illustrate the versatility of this approach, it is shown that not only insulin, but also glucagon‐like peptide 1 (GLP‐1), nanoluciferase (NLuc), and the model biopharmaceutical erythropoietin (EPO) can be trigger‐inducibly released, even when using biologically inactive insulin as a carrier. The facilitating beta cells are engineered with a controllable TRPV1‐mediated Ca2+ influx that induces the fusion of cytoplasmic storage vesicles with the membrane, leading to the release of the stored protein. When required, the growth medium is exchanged for saline solution, and the system is stimulated with the small molecule capsaicin, with a hand‐warming pack, or simply by using sunlight. Injection of insulin saline solution obtained in this way into a type‐1 diabetes mouse model results in the regulation of blood glucose levels. It is believed that this system will be readily adaptable to deliver various biopharmaceutical proteins at remote locations.

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Insulin granule biogenesis and exocytosis

Cited by 74 publications

References 165 publications

Regulatory effects of protein S-acylation on insulin secretion and insulin action

Regulatory effects of protein S-acylation on insulin secretion and insulin action

Condensation of the β‐cell secretory granule luminal cargoes pro/insulin and ICA512 RESP18 homology domain

Sunlight‐Controllable Biopharmaceutical Production for Remote Emergency Supply of Directly Injectable Therapeutic Proteins

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