Regeneration of Pancreatic Cells from Intra-Islet Precursor Cells in an Experimental Model of Diabetes

Shin

Laboratory Investigation

et al. 2007

Hepatic oval cells have shown the potential to transdifferentiate into insulin-producing cells when cultured with high glucose concentrations. However, it remains unknown whether the oval cells can contribute to insulin production in diabetic mice. In this study, our aim was to investigate the response of activated hepatic oval cells to hyperglycemic conditions. C57BL/6 mice were fed a diet containing 0.1% 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) for 4 weeks to activate the hepatic oval cell population before inducing hyperglycemia with streptozotocin (STZ). Despite the initial hyperglycemia (341715 mg/dl), the blood glucose levels of DDC-STZ-treated mice were significantly improved within 6 weeks (185712 mg/dl). During the initial hyperglycemic stage, DDC-STZ-treated livers expressed pancreatic developmental, endocrine and exocrine genes. Hepatic insulin production was confirmed by immunohistochemistry and ELISA. These results suggested that transdifferentiated hepatic oval cell population contributed to the amelioration of hyperglycemia. We additionally determined that DDC-STZ-treated pancreata played a critical role in complete reversal of hyperglycemia as evidenced by extensive b-cell regeneration and increase of pancreatic insulin content after STZ treatment, which is rarely observed in other adult STZ models. Reversal of hyperglycemia in this model seems to be accomplished by biphasic insulin augmentation, first by hepatic transdifferentiation, and followed by endogenous b-cell regeneration in the pancreas. The DDC-STZ treatment provides a novel injury model for better understanding of the functional behavior of hepatic and pancreatic stem/progenitor cell population under hyperglycemic condition, which may yield critical information for developing b-cell-based therapies to treat diabetes. The pancreatic endocrine compartment is composed of the islets of Langerhans, which are clusters of four cell types that synthesize insulin (b-cells), glucagon (a-cells), somatostatin (d-cells) and pancreatic polypeptide (pp-cells). In mature rodent pancreatic islets, b-cells are located in the core, whereas a-, d-and pp-cells are in the rim. The pancreatic bcell possesses the ability to respond to minor increases in the plasma glucose levels, thereby keeping the blood glucose level within a very narrow range. 1 Progressive destruction of pancreatic b-cell leading to decreased insulin production and subsequent hyperglycemia is observed in all forms of diabetes mellitus. Therefore, the number of functional b-cells in the pancreas is of decisive importance in the development and progress of the disease. To date, the most effective long-term treatment of diabetes is islet transplantation, a procedure known as the Edmonton protocol. 2 However, there is currently a severe shortage of pancreas donors, creating a need for new strategies to generate pancreatic b-cells either in vitro or in vivo. Pancreatic stem/progenitor cells should be considered as the primary sources to generate insulin-producing cells. However, to dat...

Section: Discussionmentioning

confidence: 87%

mentioning

confidence: 99%

Streptozotocin-induced diabetes can be reversed by hepatic oval cell activation through hepatic transdifferentiation and pancreatic islet regeneration

Shin

Laboratory Investigation

et al. 2007

“…The origin of b-cell mass expansion, which is known to occur after partial pancreatectomy, 9 STZ, 10 or interferong, 11 has been a subject of recent controversy. Dor et al 12 concluded that new islets could only be formed by replication of existing b-cells after birth or partial pancreatectomy in adult mice.…”

Section: Discussionmentioning

confidence: 99%

Reversal of streptozotocin-induced diabetes in rats by gene therapy with betacellulin and pancreatic duodenal homeobox-1

Chen

Ding

et al. 2007

Gene Ther

Ultrasound-targeted microbubble destruction (UTMD) was used to direct betacellulin (BTC) and pancreatic duodenal homeobox-1 (PDX1) to rat pancreas 48 h after islet destruction by streptozotocin (STZ). Sprague-Dawley rats were rendered diabetic by STZ injection. Controls included normal rats, STZ only without UTMD, and UTMD with DsRed reporter gene. Blood glucose increased dramatically in all rats 48 h after STZ, and continued to rise after UTMD with BTC alone. Blood glucose declined from day 3 to day 10 after UTMD with PDX1, but remained elevated (26178 mg/dl). However, in rats treated with both BTC and PDX1, blood glucose remained below 200 mg/dl throughout day 10. This was accompanied by normalization of blood insulin and C-peptide. Histology demonstrated islet-like clusters of glucagon-staining cells in the rats treated with BTC and PDX1, but these clusters disappeared by 30 days after UTMD treatment. Although regeneration of insulin-producing islets was not seen, diabetes was reversed for up to 15 days after a single UTMD treatment by ectopic insulin production by pancreatic acinar cells. These cells co-expressed amylase and insulin and demonstrated several b-cell markers by reverse transcription-PCR. Gene therapy by UTMD can reverse diabetes in vivo in adult rats by restoring pancreatic insulin production.

“…It has been proposed that these adult pancreatic stem or progenitor cells reside in the epithelium of pancreatic ducts 5,6 , inside islets 7 or in the bone marrow 8 . Others have suggested that b-cells form in the adult by transdifferentiation of pancreatic acinar cells 9 , islet cells that express hormones other than insulin 10 , or splenocytes 11 . In addition to explaining the formation of new b-cells within existing islets, it has also been suggested that whole new islets form (islet neogenesis) by clustering of new b-cells that are derived from stem cells 5,12,13 .…”

mentioning

confidence: 99%

Adult pancreatic β-cells are formed by self-duplication rather than stem-cell differentiation

Dor

Brown

Martinez

et al. 2004

Nature

2,112

1,823

generate and maintain the correct number of cells is a fundamental problem in biology. In principle, tissue turnover can occur by the differentiation of stem cells, as is well documented for blood, skin and intestine, or by the duplication of existing differentiated cells. Recent work on adult stem cells has highlighted their potential contribution to organ maintenance and repair. However, the extent to which stem cells actually participate in these processes in vivo is not clear. Here we introduce a method for genetic lineage tracing to determine the contribution of stem cells to a tissue of interest. We focus on pancreatic b-cells, whose postnatal origins remain controversial. Our analysis shows that pre-existing b-cells, rather than pluripotent stem cells, are the major source of new b-cells during adult life and after pancreatectomy in mice. These results suggest that terminally differentiated b-cells retain a significant proliferative capacity in vivo and cast doubt on the idea that adult stem cells have a significant role in b-cell replenishment.The literature on pancreatic b-cells and islets of Langerhans is replete with studies suggesting various mechanisms for b-cell homeostasis and regenerative repair. Early studies on patterns of [ 3 H]thymidine incorporation indicated that adult pancreatic endocrine cells belong to a class of tissues that could be maintained by the self-duplication of differentiated cells [1][2][3] . More recent immunohistochemical observations suggest a stem-cell origin for islet cells, including insulin-expressing b-cells 4 . It has been proposed that these adult pancreatic stem or progenitor cells reside in the epithelium of pancreatic ducts 5,6 , inside islets 7 or in the bone marrow 8 . Others have suggested that b-cells form in the adult by transdifferentiation of pancreatic acinar cells 9 , islet cells that express hormones other than insulin 10 , or splenocytes 11 . In addition to explaining the formation of new b-cells within existing islets, it has also been suggested that whole new islets form (islet neogenesis) by clustering of new b-cells that are derived from stem cells 5,12,13 . However, all of these models and suggestions are, for the most part, based on the interpretation of static histological data rather than direct lineage analysis 14 .We developed a simple method for distinguishing stem-cellderived b-cells from the progeny of pre-existing b-cells. Fully differentiated b-cells, defined here as post-natal cells transcribing the insulin gene, are heritably labelled in transgenic mice with a tamoxifen-inducible Cre/lox system ('pulse'). The label is the expression of the human alkaline phosphatase protein, which can be detected by a histochemical stain. After a long period, during which turnover occurs ('chase'), b-cells are examined for the presence of the label. Cells generated after the pulse are labelled if and only if they are the progeny of pre-existing (labelled) b-cells; new b-cells derived from any non-b source, including stem cells, are not labelled. Differ...