Tamoxifen suppresses pancreatic ß-cell proliferation in mice.

Tamoxifen is a mixed agonist/antagonist estrogen analogue that is frequently used to induce conditional gene deletion in mice using Cre-loxP mediated gene recombination. Tamoxifen is routinely employed in extremely high-doses relative to typical human doses to induce efficient gene deletion in mice. Although tamoxifen has been widely assumed to have no influence upon ß-cells, the acute developmental and functional consequences of high-dose tamoxifen upon glucose homeostasis and adult ß-cells are largely unknown. We tested if tamoxifen influences glucose homeostasis in male mice of various genetic backgrounds. We then carried out detailed histomorphometry studies of mouse pancreata. We also performed gene expression studies with islets of tamoxifen-treated mice and controls. Tamoxifen had modest effects upon glucose homeostasis of mixed genetic background (F1 B6129SF1/J) mice, with fasting hyperglycemia and improved glucose tolerance but without overt effects on fed glucose levels or insulin sensitivity. Tamoxifen inhibited proliferation of ß-cells in a dose-dependent manner, with dramatic reductions in ß-cell turnover at the highest dose (decreased by 66%). In sharp contrast, tamoxifen did not reduce proliferation of pancreatic acinar cells. ß-cell proliferation was unchanged by tamoxifen in 129S2 mice but was reduced in C57Bl6 genetic background mice (decreased by 59%). Gene expression studies revealed suppression of RNA for cyclins D1 and D2 within islets of tamoxifen-treated mice. Tamoxifen has a cytostatic effect on ß-cells, independent of changes in glucose homeostasis, in mixed genetic background and also in C57Bl6 mice. Tamoxifen should be used judiciously to inducibly inactivate genes in studies of glucose homeostasis.

Glucagon Receptor Antagonist-Stimulated α-Cell Proliferation Is Severely Restricted With Advanced Age.

Glucagon-containing α-cells potently regulate glucose homeostasis, but the developmental biology of α-cells in adults remains poorly understood. Although glucagon receptor antagonists (GRAs) have great potential as antidiabetic therapies, murine and human studies have raised concerns that GRAs might cause uncontrolled α-cell growth. Surprisingly, previous rodent GRA studies were only performed in young mice, implying that the potential impact of GRAs to drive α-cell expansion in adult patients is unclear. We assessed adaptive α-cell turnover and adaptive proliferation, administering a novel GRA (JNJ-46207382) to both young and aged mice. Basal α-cell proliferation rapidly declined soon after birth and continued to drop to very low levels in aged mice. GRA drove a 2.4-fold increase in α-cell proliferation in young mice. In contrast, GRA-induced α-cell proliferation was severely reduced in aged mice, although still present at 3.2-fold the very low basal rate of aged controls. To interrogate the lineage of GRA-induced α-cells, we sequentially administered thymidine analogs and quantified their incorporation into α-cells. Similar to previous studies of ß-cells, α-cells only divided once in both basal and stimulated conditions. Lack of contribution from highly proliferative "transit-amplifying" cells supports a model whereby α-cells expand by self-renewal and not via specialized progenitors.

Low-Level Insulin Content Within Abundant Non-ß Islet Endocrine Cells in Long-standing Type 1 Diabetes.

Although most patients with type 1 diabetes (T1D) continue to produce small amounts of insulin decades after disease onset, very few ß-cells persist within their pancreata. Consequently, the source of persistent insulin secretion within T1D remains unclear. We hypothesized that low-level insulin content within non-ß-cells could underlie persistent T1D insulin secretion. We tested for low levels of insulin (insulinlow) within a large cohort of JDRF Network for Pancreatic Organ Donors With Diabetes (nPOD) human pancreata across a wide range of ages and T1D disease durations. Long exposures, high-throughput imaging, and blinded parallel examiners allowed precise quantification of insulinlow cells. Of note, abundant islet endocrine cells with low quantities of insulin were present in most T1D pancreata. Insulinlow islet abundance and composition were not influenced by age, duration of diabetes, or age of onset. Insulinlow islets also contained ß-cell markers at variable levels, including Pdx1, Nkx6.1, GLUT1, and PC1/3. Most insulinlow cells contained abundant glucagon and other α-cell markers, suggesting that α-cells drive much of the insulinlow phenotype in T1D. However, pancreatic polypeptide, somatostatin, and ghrelin cells also contributed to the insulinlow cell population. Insulinlow cells represent a potential source of persistent insulin secretion in long-standing T1D and a possible target for regenerative therapies to expand ß-cell function in disease.

Highly Proliferative α-Cell-Related Islet Endocrine Cells in Human Pancreata.

The proliferative response of non-ß islet endocrine cells in response to type 1 diabetes (T1D) remains undefined. We quantified islet endocrine cell proliferation in a large collection of nondiabetic control and T1D human pancreata across a wide range of ages. Surprisingly, islet endocrine cells with abundant proliferation were present in many adolescent and young-adult T1D pancreata. But the proliferative islet endocrine cells were also present in similar abundance within control samples. We queried the proliferating islet cells with antisera against various islet hormones. Although pancreatic polypeptide, somatostatin, and ghrelin cells did not exhibit frequent proliferation, glucagon-expressing α-cells were highly proliferative in many adolescent and young-adult samples. Notably, α-cells only comprised a fraction (∼1/3) of the proliferative islet cells within those samples; most proliferative cells did not express islet hormones. The proliferative hormone-negative cells uniformly contained immunoreactivity for ARX (indicating α-cell fate) and cytoplasmic Sox9 (Sox9Cyt). These hormone-negative cells represented the majority of islet endocrine Ki67+ nuclei and were conserved from infancy through young adulthood. Our studies reveal a novel population of highly proliferative ARX+ Sox9Cyt hormone-negative cells and suggest the possibility of previously unrecognized islet development and/or lineage plasticity within adolescent and adult human pancreata.

ß Cells Persist in T1D Pancreata Without Evidence of Ongoing ß-Cell Turnover or Neogenesis.

Context: The cellular basis of persistent ß-cell function in type 1 diabetes (T1D) remains enigmatic. No extensive quantitative ß-cell studies of T1D pancreata have been performed to test for ongoing ß-cell regeneration or neogenesis. Objective: We sought to determine the mechanism of ß-cell persistence in T1D pancreata. Design: We studied T1D (n = 47) and nondiabetic control (n = 59) pancreata over a wide range of ages from the Juvenile Diabetes Research Foundation Network of Pancreatic Organ Donors with Diabetes via high-throughput microscopy. Intervention and Main Outcome Measures: We quantified ß-cell mass, ß-cell turnover [via Ki-67 and terminal deoxynucleotide transferase-mediated dUTP nick end labeling (TUNEL)], islet ductal association, and insulin/glucagon coexpression in T1D and control pancreata. Results: Residual insulin-producing ß cells were detected in some (but not all) T1D cases of varying disease duration. Several T1D pancreata had substantial numbers of ß cells. Although ß-cell proliferation was prominent early in life, it dramatically declined after infancy in both nondiabetic controls and T1D individuals. However, ß-cell proliferation was equivalent in control and T1D pancreata. ß-cell death (assessed by TUNEL) was extremely rare in control and T1D pancreata. Thus, ß-cell turnover was not increased in T1D. Furthermore, we found no evidence of small islet/ductal neogenesis or α-cell to ß-cell transdifferentiation in T1D pancreata, regardless of disease duration. Conclusion: Longstanding ß-cell function in patients with T1D appears to be largely a result of ß cells that persist, without any evidence of attempted ß-cell regeneration, small islet/ductal neogenesis, or transdifferentiation from other islet endocrine cell types.

Incretin Therapies Do Not Expand ß-Cell Mass or Alter Pancreatic Histology in Young Male Mice.

The impact of incretins upon pancreatic ß-cell expansion remains extremely controversial. Multiple studies indicate that incretin-based therapies can increase ß-cell proliferation, and incretins have been hypothesized to expand ß-cell mass. However, disagreement exists on whether incretins increase ß-cell mass. Moreover, some reports indicate that incretins may cause metaplastic changes in pancreatic histology. To resolve these questions, we treated a large cohort of mice with incretin-based therapies and carried out a rigorous analysis of ß-cell turnover and pancreatic histology using high-throughput imaging. Young mice received exenatide via osmotic pump, des-fluoro-sitagliptin, or glipizide compounded in diet for 2 weeks (short-term) on a low-fat diet (LFD) or 4.5 months (long-term) on a LFD or high-fat diet (HFD). Pancreata were quantified for ß-cell turnover and mass. Slides were examined for gross anatomical and microscopic changes to exocrine pancreas. Short-term des-fluoro-sitagliptin increased serum insulin and induced modest ß-cell proliferation but no change in ß-cell mass. Long-term incretin therapy in HFD-fed mice resulted in reduced weight gain, improved glucose homeostasis, and abrogated ß-cell mass expansion. No evidence for rapidly dividing progenitor cells was found in islets or pancreatic parenchyma, indicating that incretins do not induce islet neogenesis or pancreatic metaplasia. Contrasting prior reports, we found no evidence of ß-cell mass expansion after acute or chronic incretin therapy. Chronic incretin administration was not associated with histological abnormalities in pancreatic parenchyma; mice did not develop tumors, pancreatitis, or ductal hyperplasia. We conclude that incretin therapies do not generate ß-cells or alter pancreatic histology in young mice.

Resolving Discrepant Findings on ANGPTL8 in ß-Cell Proliferation: A Collaborative Approach to Resolving the Betatrophin Controversy.

The ß-cell mitogenic effects of ANGPTL8 have been subjected to substantial debate. The original findings suggested that ANGPTL8 overexpression in mice induced a 17-fold increase in ß-cell proliferation. Subsequent studies in mice contested this claim, but a more recent report in rats supported the original observations. These conflicting results might be explained by variable ANGPTL8 expression and differing methods of ß-cell quantification. To resolve the controversy, three independent labs collaborated on a blinded study to test the effects of ANGPTL8 upon ß-cell proliferation. Recombinant human betatrophin (hBT) fused to maltose binding protein (MBP) was delivered to mice by intravenous injection. The results demonstrate that ANGPTL8 does not stimulate significant ß-cell proliferation. Each lab employed different methods for ß-cell identification, resulting in variable quantification of ß-cell proliferation and suggests a need for standardizing practices for ß-cell quantification. We also observed a new action of ANGPTL8 in stimulating CD45+ hematopoietic-derived cell proliferation which may explain, in part, published discrepancies. Overall, the hypothesis that ANGPTL8 induces dramatic and specific ß-cell proliferation can no longer be supported. However, while ANGPTL8 does not stimulate robust ß-cell proliferation, the original experimental model using drug-induced (S961) insulin resistance was validated in subsequent studies, and thus still represents a robust system for studying signals that are either necessary or sufficient for ß-cell expansion. As an added note, we would like to commend collaborative group efforts, with repetition of results and procedures in multiple laboratories, as an effective method to resolve discrepancies in the literature.

Extreme obesity induces massive beta cell expansion in mice through self-renewal and does not alter the beta cell lineage.

AIMS/HYPOTHESIS: Understanding the developmental biology of beta cell regeneration is critical for developing new diabetes therapies. Obesity is a potent but poorly understood stimulus for beta cell expansion. Current models of obesity are complicated by developmental compensation or concurrent diabetes, limiting their usefulness for identifying the lineage mechanism(s) of beta cell expansion. We aimed to determine whether acute inducible obesity stimulates beta cell expansion and to determine the lineage mechanism of beta cell growth in obesity. METHODS: We created whole-body tamoxifen-inducible leptin receptor (LepR)-deficient mice (Ubc-Cre (ERT2) LepR (loxP/loxP) ) as a novel model of acute obesity. Beta cell mass and proliferation were quantified after short-term LepR deletion. Clonal analysis of beta cell expansion using the Brainbow2.1 reporter was performed 6 months post tamoxifen initiation. RESULTS: LepR deficiency induced a doubling of body mass within 3 weeks, with moderate glucose intolerance (unlike typical LepR mutant mice [db/db], which have frank diabetes). Beta cell mass expanded threefold through increased beta cell proliferation, without evidence for contribution from specialised progenitors or stem cells (via sequential thymidine labelling and Brainbow2.1 reporter). Thus, self-renewal is the primary lineage mechanism in obesity-induced beta cell expansion. However, even the rapid beta cell proliferation could not exceed the restrictions of the replication refractory period. CONCLUSIONS/INTERPRETATION: In summary, we created a novel model of inducible obesity demonstrating that even extreme metabolic demand does not alter beta cell lineage.

Extreme Beta-Cell Deficiency in Pancreata of Dogs with Canine Diabetes.

The pathophysiology of canine diabetes remains poorly understood, in part due to enigmatic clinical features and the lack of detailed histopathology studies. Canine diabetes, similar to human type 1 diabetes, is frequently associated with diabetic ketoacidosis at onset or after insulin omission. However, notable differences exist. Whereas human type 1 diabetes often occurs in children, canine diabetes is typically described in middle age to elderly dogs. Many competing theories have been proposed regarding the underlying cause of canine diabetes, from pancreatic atrophy to chronic pancreatitis to autoimmune mediated ß-cell destruction. It remains unclear to what extent ß-cell loss contributes to canine diabetes, as precise quantifications of islet morphometry have not been performed. We used high-throughput microscopy and automated image processing to characterize islet histology in a large collection of pancreata of diabetic dogs. Diabetic pancreata displayed a profound reduction in ß-cells and islet endocrine cells. Unlike humans, canine non-diabetic islets are largely comprised of ß-cells. Very few ß-cells remained in islets of diabetic dogs, even in pancreata from new onset cases. Similarly, total islet endocrine cell number was sharply reduced in diabetic dogs. No compensatory proliferation or lymphocyte infiltration was detected. The majority of pancreata had no evidence of pancreatitis. Thus, canine diabetes is associated with extreme ß-cell deficiency in both new and longstanding disease. The ß-cell predominant composition of canine islets and the near-total absence of ß-cells in new onset elderly diabetic dogs strongly implies that similar to human type 1 diabetes, ß-cell loss underlies the pathophysiology of canine diabetes.

Angiopoietin-like protein 8 (ANGPTL8)/betatrophin overexpression does not increase beta cell proliferation in mice.

AIMS/HYPOTHESIS: The identification of novel targets that stimulate endogenous regeneration of beta cells would represent a significant advance in the treatment of patients with diabetes. The betatrophin hypothesis suggests that increased expression of angiopoietin-like protein 8 (ANGPTL8) induces dramatic and specific beta cell proliferation and subsequent beta cell mass expansion with improved glucose tolerance. In light of recent controversy, we further investigated the effects of ANGPTL8 overexpression on beta cell proliferation. METHODS: We performed hydrodynamic tail vein injections of green fluorescent protein (GFP) or Angptl8 (also known as Gm6484) DNA in multiple cohorts of mice of different ages. We employed state-of-the-art methods to comprehensively quantify beta cell mass and proliferation, controlling for mouse age, genetic strain, source of DNA injected, Angptl8 gene expression and proliferation markers. RESULTS: In two young and two aged cohorts of B6.129 mice, no substantial change in beta cell replication, mass or glucose homeostasis was observed following ANGPTL8 overexpression. Even in mice with extremely elevated Angptl8 expression (26-fold increase), beta cell replication was not significantly altered. Finally, we considered mice on the ICR background exactly as studied by Melton and colleagues, and still no beta cell mitogenic effect was detected following ANGPTL8 overexpression. CONCLUSION/INTERPRETATION: ANGPTL8 does not stimulate beta cell replication in young or old mice.

Large-scale discovery of ERK2 substrates identifies ERK-mediated transcriptional regulation by ETV3.

The mitogen-activated protein kinase (MAPK) extracellular signal-regulated kinase 2 (ERK2) is ubiquitously expressed in mammalian tissues and is involved in a wide range of biological processes. Although MAPKs have been intensely studied, identification of their substrates remains challenging. We have optimized a chemical genetic system using analog-sensitive ERK2, a form of ERK2 engineered to use an analog of adenosine 5'-triphosphate (ATP), to tag and isolate ERK2 substrates in vitro. This approach identified 80 proteins phosphorylated by ERK2, 13 of which are known ERK2 substrates. The 80 substrates are associated with diverse cellular processes, including regulation of transcription and translation, mRNA processing, and regulation of the activity of the Rho family guanosine triphosphatases. We found that one of the newly identified substrates, ETV3 (a member of the E twenty-six family of transcriptional regulators), was extensively phosphorylated on sites within canonical and noncanonical ERK motifs. Phosphorylation of ETV3 regulated transcription by preventing its binding to DNA at promoters for several thousand genes, including some involved in negative feedback regulation of itself and of upstream signals.