References of "Lavergne, Arnaud"
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See detailIdentification of Signaling Pathways Regulating Beta Cell Regeneration in Zebrafish
Massoz, Laura; Bergemann, David ULiege; Lavergne, Arnaud ULiege et al

Conference (2017, September 15)

Diabetes is becoming a leading health issue worldwide. It occurs under insulin resistance/deficiency and when insulin-producing pancreatic beta-cell mass is dramatically reduced. Besides therapeutic ... [more ▼]

Diabetes is becoming a leading health issue worldwide. It occurs under insulin resistance/deficiency and when insulin-producing pancreatic beta-cell mass is dramatically reduced. Besides therapeutic strategies to preserve beta-cell mass and function and improve insulin treatments, beta-cell replacement constitutes a promising alternative to replenish the pancreas with functional beta-cells. Beta-cell neogenesis can be achieved from different pancreatic cell types leading to the hope that triggering regeneration could be harnessed in future therapies. Still, mammals show limited regenerative capabilities, making difficult the study of these mechanisms. In contrast, zebrafish is extensively used for regeneration studies notably of beta-cells. We recently showed that the adult zebrafish ducts display characteristics of embryonic pancreatic progenitors that give rise to beta-cells in physiological and induced diabetic condition*. To better understand the molecular mechanisms underlying this potential, genes and signaling pathways regulated in the zebrafish pancreatic ducts after beta-cell ablation have been identified by transcriptomic profiling. For functional studies, we have developed an assay using 7-20 days old larvae to investigate the role of selected candidate pathways in beta-cell regeneration with pharmacological inhibitors/activators and by transgenic overexpression of candidate signaling factors. These results should provide new hints to help improve regenerative competences in mammals. [less ▲]

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See detailToward discovery of novel key genes for pancreatic beta cell regeneration in zebrafish
Carril Pardo, Claudio Andrès ULiege; Bergemann, David ULiege; Massoz, Laura ULiege et al

Poster (2017, September 14)

Diabetes is becoming a leading health issue worldwide. It occurs under insulin resistance/deficiency and when insulin-producing pancreatic beta-cell mass is dramatically reduced. Besides therapeutic ... [more ▼]

Diabetes is becoming a leading health issue worldwide. It occurs under insulin resistance/deficiency and when insulin-producing pancreatic beta-cell mass is dramatically reduced. Besides therapeutic strategies to preserve beta-cell mass and function and improve insulin treatments, beta-cell replacement constitutes a promising alternative to replenish the pancreas with functional beta-cells. Several observations of pancreatic cell plasticity has led to the hope that triggering beta-cell regeneration within the pancreas could be harnessed in future therapies. Still, mammals show limited regenerative capabilities, making difficult the study of these mechanisms. In contrast, zebrafish is extensively used for regeneration studies notably of beta-cells. We recently showed that the adult zebrafish ducts display characteristics of embryonic pancreatic progenitors that can give rise to beta-cells in physiological and induced diabetic condition*, and we determined the transcriptomic profile of zebrafish pancreatic ducts during beta-cell regeneration. To identify new genes crucial for beta-cell regeneration we plan to investigate the role of about 10 selected candidate genes by analyzing invalidating mutations created by CRISPR/Cas9. Their effect on beta-cell regeneration will be studied in 7-20 old larvae which we have established as experimental platform for functional studies. This project should help decipher the molecular mechanism of beta-cell regeneration. [less ▲]

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See detailPancreatic Beta Cell Regeneration: Duct Cells Act as Progenitors in Adult Zebrafish
Bergemann, David ULiege; Ghaye, Aurélie; Tarifeño Saldivia, Estefania ULiege et al

Poster (2016, March 18)

Diabetes is characterized by the loss of insulin producing beta cells. Although different therapeutic strategies do exist, they lack precise and dynamic control of glycemia as carried out by endogenous ... [more ▼]

Diabetes is characterized by the loss of insulin producing beta cells. Although different therapeutic strategies do exist, they lack precise and dynamic control of glycemia as carried out by endogenous beta cells. One promising alternative is to replenish the pancreas with bona fide functional beta cells by triggering regeneration mechanisms. Previous studies have shown beta cell neogenesis but still remain controversial about their origin as they used different models. However, among the different hypotheses, it is tempting to assume that pancreatic ducts contain progenitor/precursor cells in adults. The latter is supported by the fact that the embryonic duct epithelium gives rise to the endocrine lineage, and that in healthy and diabetic human adults, insulin positive cells could be found next to or in pancreatic ducts. Despite these observations, mammals show very limited regenerative capabilities, making it difficult to investigate those mechanisms. In contrast, zebrafish are extensively used for regeneration studies. The ability of adult zebrafish to regenerate its beta cells and restore normoglycemia after massive beta cell ablation has already been shown. Our work focuses on the understanding of the underlying mechanisms leading to this retained potential. Here we show that adult pancreatic duct cells act as progenitors, giving rise to beta cells, in physiological and induced diabetic condition in vivo. To get insight into this process, we conducted RNA-seq experiments on zebrafish pancreatic duct cells. By this mean we could identify new ductal markers and noticed that adult duct cells also show strong expression of embryonic pancreatic progenitor markers. In our ongoing comparative analyses we are deciphering the key genes and pathways needed to set in motion the regenerative machinery. The differences between zebrafish and mammal duct cells that will thereby be underlined might then be transposed to mammalian model s to restore regenerative processes. [less ▲]

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