Projecten per jaar
Samenvatting
Introduction: The transferrin receptor (TFRC) is abundant on
the surface of ß-cells compared to neighboring α- and ∂-cells, suggesting
an important role of iron in ß-cell biology. The precise
impact of iron on ß-cell development, function, and survival
remains elusive. Here, we investigated the role of iron metabolism
in mouse and human ß-cells through chemical and genetic modulation
of iron supply.
Methods: To chemically modulate iron levels, mouse and
human pancreatic islets, EndoC-ßH1 and human induced pluripotent
stem cell (iPSC)-derived ß-cells were exposed to deferoxamine
(DFO) or ferric citrate (FeCitr) for 24 hours to induce iron
depletion or overload, respectively. Genetic iron deficiency was
investigated using ß-cell-specific conditional (Ins1-Cre;Tfrcfl/fl or
ß-Tfrc-KO) and inducible (Ins1-CreERT;Tfrcfl/fl or ß-Tfrc-iKO)
Tfrc knockout mouse models, as well as an α-cell-specific (Gcg-
Cre; Tfrcfl/fl) knockout.
Results: Chemical iron depletion increased TFRC expression
in primary mouse and human islets, EndoC-ßH1 and iPSCderived
ß-cells, while iron overload decreased TFRC expression.
Iron depletion in iPSC-derived pancreatic endocrine precursor
cells (stage 5 of differentiation) resulted in significant cell death. In
subsequent stages of differentiation, cells became more resistant to
iron depletion, and the viability of long-cultured iPSC-derived
ß-cell aggregates was unaffected. Genetic iron deficiency in mouse
ß-cells (ß-Tfrc-KO) led to ß-cell loss and the onset of diabetes from
5 weeks of age onward, which iron injections could prevent.
Induction of genetic iron deficiency in neonatal ß-cells (ß-TfrciKO,
induction at postnatal day 5) resulted in elevated blood glucose
levels and impaired glucose tolerance, while no discernible
effect was observed in adult ß-cells (ß-Tfrc-iKO, induction at 10
weeks). Genetic iron deficiency in α-cells did not impact their
function or survival.
Conclusions: ß-cells demonstrate unique age and maturationdependent
responses to alterations in iron supply within the endocrine
pancreas. TFRC-mediated iron import is crucial for ß-cell
survival and function during ß-cell development, whereas this
becomes dispensable in adulthood and mature stages of iPSCderived
ß-cell differentiation. These findings underscore an intricate
relationship between iron metabolism and developmental
ß-cell physiology, offering potential implications for improving
the functional maturation of stem cell-derived ß-cells.
the surface of ß-cells compared to neighboring α- and ∂-cells, suggesting
an important role of iron in ß-cell biology. The precise
impact of iron on ß-cell development, function, and survival
remains elusive. Here, we investigated the role of iron metabolism
in mouse and human ß-cells through chemical and genetic modulation
of iron supply.
Methods: To chemically modulate iron levels, mouse and
human pancreatic islets, EndoC-ßH1 and human induced pluripotent
stem cell (iPSC)-derived ß-cells were exposed to deferoxamine
(DFO) or ferric citrate (FeCitr) for 24 hours to induce iron
depletion or overload, respectively. Genetic iron deficiency was
investigated using ß-cell-specific conditional (Ins1-Cre;Tfrcfl/fl or
ß-Tfrc-KO) and inducible (Ins1-CreERT;Tfrcfl/fl or ß-Tfrc-iKO)
Tfrc knockout mouse models, as well as an α-cell-specific (Gcg-
Cre; Tfrcfl/fl) knockout.
Results: Chemical iron depletion increased TFRC expression
in primary mouse and human islets, EndoC-ßH1 and iPSCderived
ß-cells, while iron overload decreased TFRC expression.
Iron depletion in iPSC-derived pancreatic endocrine precursor
cells (stage 5 of differentiation) resulted in significant cell death. In
subsequent stages of differentiation, cells became more resistant to
iron depletion, and the viability of long-cultured iPSC-derived
ß-cell aggregates was unaffected. Genetic iron deficiency in mouse
ß-cells (ß-Tfrc-KO) led to ß-cell loss and the onset of diabetes from
5 weeks of age onward, which iron injections could prevent.
Induction of genetic iron deficiency in neonatal ß-cells (ß-TfrciKO,
induction at postnatal day 5) resulted in elevated blood glucose
levels and impaired glucose tolerance, while no discernible
effect was observed in adult ß-cells (ß-Tfrc-iKO, induction at 10
weeks). Genetic iron deficiency in α-cells did not impact their
function or survival.
Conclusions: ß-cells demonstrate unique age and maturationdependent
responses to alterations in iron supply within the endocrine
pancreas. TFRC-mediated iron import is crucial for ß-cell
survival and function during ß-cell development, whereas this
becomes dispensable in adulthood and mature stages of iPSCderived
ß-cell differentiation. These findings underscore an intricate
relationship between iron metabolism and developmental
ß-cell physiology, offering potential implications for improving
the functional maturation of stem cell-derived ß-cells.
| Originele taal-2 | English |
|---|---|
| Pagina's | 486 |
| Aantal pagina's | 487 |
| Status | Published - 16 nov. 2024 |
| Evenement | 62nd Annual Meeting of the European Society for Pediatric Endocrinology (ESPE) - Liverpool , Liverpool, United Kingdom Duur: 16 nov. 2024 → 18 nov. 2024 https://www.eurospe.org/event/62nd-espe-meeting/ |
Conference
| Conference | 62nd Annual Meeting of the European Society for Pediatric Endocrinology (ESPE) |
|---|---|
| Land/Regio | United Kingdom |
| Stad | Liverpool |
| Periode | 16/11/24 → 18/11/24 |
| Internet adres |
Projecten
- 3 Actief
-
FWOTM1142: Het ontraadselen van de betrokkenheid van ijzermetabolisme in beta cel differentiatie, maturatie en functie
Staels, W., De Leu, N., Heimberg, H. & Van Mulders, A.
1/11/22 → 31/10/26
Project: Fundamenteel
-
FWOAL1035: Ontrafeling van de rol van ijzer metabolisme in beta-cel differentiatie, maturatie en functie.
1/01/22 → 31/12/25
Project: Fundamenteel
-
FWOTM1035: De rol van ijzer metabolisme in bèta-cell differentiatie, maturatie en functie.
1/10/20 → 30/09/25
Project: Fundamenteel