Beta cells transfer vesicles containing insulin to phagocytes for presentation to T cells

Vomund, Anthony N.; Zinselmeyer, Bernd H.; Hughes, Jing; Calderon, Boris; Valderrama, Carolina; Ferris, Stephen T.; Wan, Xiaoxiao; Kanekura, Kohsuke; Carrero, Javier A.; Urano, Fumihiko; Unanue, Emil R.

doi:10.1073/pnas.1515954112

Cited by 91 publications

(103 citation statements)

References 42 publications

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“…However, the mechanism leading to this delayed antibody response was not investigated in this study (Satoh et al 2011). A recent elegant publication showed that β-cells transfer antigenic epitopes to antigen presenting cells via a direct membrane contact (Vomund et al 2015). This is a novel mechanism, however, not specific for 'diabetic' β-cells, since it was observed in both diabetic and nondiabetic mice and in nondiabetic humans.…”

Section: Er Stress and Antigen Presentationmentioning

confidence: 87%

“…This is a novel mechanism, however, not specific for 'diabetic' β-cells, since it was observed in both diabetic and nondiabetic mice and in nondiabetic humans. Interestingly, high glucose increased the transfer of epitopes (Vomund et al 2015). The mechanism for this increase has not been yet investigated, but it would be interesting to verify whether it is not due to high glucose-induced ER stress.…”

Section: Er Stress and Antigen Presentationmentioning

confidence: 99%

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Endoplasmic reticulum stress and the unfolded protein response in pancreatic islet inflammation

Meyerovich

Ortis

Allagnat

et al. 2016

Journal of Molecular Endocrinology

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Insulin-secreting pancreatic β-cells are extremely dependent on their endoplasmic reticulum (ER) to cope with the oscillatory requirement of secreted insulin to maintain normoglycemia. Insulin translation and folding rely greatly on the unfolded protein response (UPR), an array of three main signaling pathways designed to maintain ER homeostasis and limit ER stress. However, prolonged or excessive UPR activation triggers alternative molecular pathways that can lead to β-cell dysfunction and apoptosis. An increasing number of studies suggest a role of these pro-apoptotic UPR pathways in the downfall of β-cells observed in diabetic patients. Particularly, the past few years highlighted a cross talk between the UPR and inflammation in the context of both type 1 (T1D) and type 2 diabetes (T2D). In this article, we describe the recent advances in research regarding the interplay between ER stress, the UPR, and inflammation in the context of β-cell apoptosis leading to diabetes.

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Section: Er Stress and Antigen Presentationmentioning

confidence: 87%

Section: Er Stress and Antigen Presentationmentioning

confidence: 99%

Endoplasmic reticulum stress and the unfolded protein response in pancreatic islet inflammation

Meyerovich

Ortis

Allagnat

et al. 2016

Journal of Molecular Endocrinology

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“…Like other resident macrophages, islet macrophages are also likely to be important in phagocytosing dead or dying cells and debris and maintaining islet cell homeostasis. Islet macrophages continuously sample antigen from beta cells [17] and, through surveying the blood vessels and islet milieu for danger signals and invading pathogens, also act as an important first line of immunological defence. Mice lacking tissue resident macrophages have reduced beta cell mass [18] and, more recently, macrophages have been found to play an important role in beta cell proliferation and regeneration in models of acute beta cell loss [19][20][21].…”

Section: Islet Macrophages In Health and Diseasementioning

confidence: 99%

“…Evidence exists for chronic beta cell-derived cues that macrophages respond to, including the accumulation of IAPP aggregates in type 2 diabetes, which induce a robust inflammatory response [8,9,12]. Intriguingly, intact insulin granules have also been observed within islet macrophages, indicative of an intimate interaction between these cell types [17].…”

Section: Beta Cell-islet Macrophage Crosstalkmentioning

confidence: 99%

When beta cells talk back

2017

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“…Although insulin is by far the major secreted product of primary beta cells, this cell type likely expresses hundreds of other secreted proteins [52], several of which have known physiological roles [52][53][54]. Future studies should also address the completeness of insulin processing, as it is possible that improperly processed and/or secreted insulin can provoke or accelerate beta cell directed autoimmunity [55].…”

Section: Remaining Obstacles-deep Phenotypingmentioning

confidence: 99%

The quest to make fully functional human pancreatic beta cells from embryonic stem cells: climbing a mountain in the clouds

Johnson

2016

Diabetologia

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The production of fully functional insulin-secreting cells to treat diabetes is a major goal of regenerative medicine. In this article, I review progress towards this goal over the last 15 years from the perspective of a beta cell biologist. I describe the current state-of-the-art, and speculate on the general approaches that will be required to identify and achieve our ultimate goal of producing functional beta cells. The need for deeper phenotyping of heterogeneous cultures of stem cell derived islet-like cells in parallel with a better understanding of the heterogeneity of the target cell type(s) is emphasised. This deep phenotyping should include high-throughput single-cell analysis, as well as comprehensive 'omics technologies to provide unbiased characterisation of cell products and human beta cells. There are justified calls for more detailed and well-powered studies of primary human pancreatic beta cell physiology, and I propose online databases of standardised human beta cell responses to physiological stimuli, including both functional and metabolomic/proteomic/ transcriptomic profiles. With a concerted, community-wide effort, including both basic and applied scientists, beta cell replacement will become a clinical reality for patients with diabetes.Keywords Embryonic stem cells . Glucose-stimulated insulin release . Human pancreatic islet beta cells . Review Abbreviation PDX1 Pancreatic and duodenal homeobox 1The case for beta cell replacement in diabetes Diabetes mellitus was recognised early in the era of regenerative medicine research as an obvious indication for a stem cell based therapy. Type 1 diabetes results from the loss of more than 80% of an individual's pancreatic beta cells, while type 2 diabetes occurs when there is insufficient functional beta cell mass to meet the body's needs. The replacement of lost or dysfunctional beta cells in all patients that require it is one of the most important, but elusive, goals of diabetes research. The rationale for beta cell replacement is clear, given the success with which islet cell transplants reduce dangerous hypoglycaemic events and slow the progression of complications [1][2][3]. Pancreatic beta cells have evolved as master regulators of metabolic homeostasis, sensing glucose and other nutrients and releasing appropriate insulin to induce their storage. We understand the basics of beta cell biology, especially the ionic mechanisms underlying insulin release in response to large and abrupt glucose stimuli, which include a rapid rise in cytosolic Ca 2+ subsequent to the metabolismdriven closure of K ATP channels, as well as a plethora of coupling factors [4]. However, we do not understand precisely how human beta cells respond to physiological stimuli and make fate decisions.There are a number of possible ways to replace beta cells in patients with diabetes. Beta cell proliferation could theoretically be induced from the few remaining beta cells in people Electronic supplementary material The online version of this article

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Beta cells transfer vesicles containing insulin to phagocytes for presentation to T cells

Cited by 91 publications

References 42 publications

Endoplasmic reticulum stress and the unfolded protein response in pancreatic islet inflammation

Endoplasmic reticulum stress and the unfolded protein response in pancreatic islet inflammation

When beta cells talk back

The quest to make fully functional human pancreatic beta cells from embryonic stem cells: climbing a mountain in the clouds

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