Projecten per jaar
Samenvatting
Introduction: Regenerating endogenous pancreatic β-cells is a
potentially curative yet currently elusive strategy for diabetes therapy.
Mimicking the microenvironment of the developing pancreas
and leveraging vascular signals, critical to pancreatic endocrinogenesis,
may promote β-cell regeneration. We aimed to investigate
whether recovery from experimental hypovascularization of the
endocrine pancreas could trigger mouse ß-cell proliferation.
Methods: A doxycycline (DOX)-inducible transgenic mouse
model was used to induce conditional intra-islet hypovascularization.
In this model, VEGF-A signaling within pancreatic islets is
antagonized through ß-cell-specific overexpression of a VEGF-A
decoy receptor, soluble fms-like tyrosine kinase 1 (sFLT1).
Cessation of sFLT1 overexpression was induced by DOX withdrawal.
sFLT1 expression, vessel kinetics, and ß-proliferation
upon DOX treatment and withdrawal were analyzed using
RT-qPCR and immunostainings. Single-cell RNA sequencing was
used to investigate the effects on the islet cells’ transcriptome and
perform pathway enrichment analysis. RIP-rtTA;TetO-GFP mice
were studied in parallel to assess the dependency of cell cycle
induction on vessel manipulation. Additionally, the results were
confirmed through in vitro experiments.
Results: Serendipitously, we found that transgene overexpression
in β-cells induces endoplasmic reticulum (ER) stress and that
subsequent relief from this stress stimulated ß-cell proliferation
independent of vessel recovery. Similarly, transient GFP overexpression
in vivo and transient chemical induction of ER stress in
vitro replicated the increased β-cell cycling response.
Conclusions: Our findings highlight the potential side effects
of ER stress due to transgene overexpression in ß-cells and assert
that ER stress relief serves as a potent regenerative stimulus.
potentially curative yet currently elusive strategy for diabetes therapy.
Mimicking the microenvironment of the developing pancreas
and leveraging vascular signals, critical to pancreatic endocrinogenesis,
may promote β-cell regeneration. We aimed to investigate
whether recovery from experimental hypovascularization of the
endocrine pancreas could trigger mouse ß-cell proliferation.
Methods: A doxycycline (DOX)-inducible transgenic mouse
model was used to induce conditional intra-islet hypovascularization.
In this model, VEGF-A signaling within pancreatic islets is
antagonized through ß-cell-specific overexpression of a VEGF-A
decoy receptor, soluble fms-like tyrosine kinase 1 (sFLT1).
Cessation of sFLT1 overexpression was induced by DOX withdrawal.
sFLT1 expression, vessel kinetics, and ß-proliferation
upon DOX treatment and withdrawal were analyzed using
RT-qPCR and immunostainings. Single-cell RNA sequencing was
used to investigate the effects on the islet cells’ transcriptome and
perform pathway enrichment analysis. RIP-rtTA;TetO-GFP mice
were studied in parallel to assess the dependency of cell cycle
induction on vessel manipulation. Additionally, the results were
confirmed through in vitro experiments.
Results: Serendipitously, we found that transgene overexpression
in β-cells induces endoplasmic reticulum (ER) stress and that
subsequent relief from this stress stimulated ß-cell proliferation
independent of vessel recovery. Similarly, transient GFP overexpression
in vivo and transient chemical induction of ER stress in
vitro replicated the increased β-cell cycling response.
Conclusions: Our findings highlight the potential side effects
of ER stress due to transgene overexpression in ß-cells and assert
that ER stress relief serves as a potent regenerative stimulus.
| Originele taal-2 | English |
|---|---|
| Pagina's | 316 |
| Aantal pagina's | 317 |
| 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 |
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AIIFUND117: VASC-ENHANCE: gebruik maken van vasculaire signalen voor verbeterde rijping van van iPSC afgeleide bèta-achtige cellen
1/02/24 → 31/01/29
Project: Fundamenteel
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FWOTM1035: De rol van ijzer metabolisme in bèta-cell differentiatie, maturatie en functie.
1/10/20 → 30/09/25
Project: Fundamenteel
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FWOSB94: Microvascular remodeling for beta(-like) cell differentiation, regeneration and transplantation
1/11/20 → 31/10/24
Project: Fundamenteel