Phagocytosis by macrophages promotes pancreatic ß cell mass reduction after parturition in mice.

Elucidating the mechanism(s) modulating appropriate tissue size is a critical biological issue. Pancreatic ß cells increase during pregnancy via cellular proliferation, but how ß cells promptly decrease to the original amount after parturition remains unclear. Herein, we demonstrate the role and mechanism of macrophage accumulation in this process. In the final stage of pregnancy, HTR1D signaling upregulates murine ß cell CXCL10, thereby promoting macrophage accumulation in pancreatic islets via the CXCL10-CXCR3 axis. Blocking this mechanism by administering an HTR1D antagonist or the CXCR3 antibody and depleting islet macrophages inhibited postpartum ß cell mass reduction. ß cells engulfed by macrophages increased in postpartum islets, but Annexin V administration suppressed this engulfment and the postpartum ß cell mass reduction, indicating the accumulated macrophages to phagocytose ß cells. This mechanism contributes to both maintenance of appropriate ß cell mass and glucose homeostasis promptly adapting to reduced systemic insulin demand after parturition.

A highly sensitive strategy for monitoring real-time proliferation of targeted cell types in vivo.

Cell proliferation processes play pivotal roles in timely adaptation to many biological situations. Herein, we establish a highly sensitive and simple strategy by which time-series showing the proliferation of a targeted cell type can be quantitatively monitored in vivo in the same individuals. We generate mice expressing a secreted type of luciferase only in cells producing Cre under the control of the Ki67 promoter. Crossing these with tissue-specific Cre-expressing mice allows us to monitor the proliferation time course of pancreatic ß-cells, which are few in number and weakly proliferative, by measuring plasma luciferase activity. Physiological time courses, during obesity development, pregnancy and juvenile growth, as well as diurnal variation, of ß-cell proliferation, are clearly detected. Moreover, this strategy can be utilized for highly sensitive ex vivo screening for proliferative factors for targeted cells. Thus, these technologies may contribute to advancements in broad areas of biological and medical research.

Inter-organ insulin-leptin signal crosstalk from the liver enhances survival during food shortages.

Crosstalk among organs/tissues is important for regulating systemic metabolism. Here, we demonstrate inter-organ crosstalk between hepatic insulin and hypothalamic leptin actions, which maintains survival during food shortages. In inducible liver insulin receptor knockout mice, body weight is increased with hyperphagia and decreased energy expenditure, accompanied by increased circulating leptin receptor (LepR) and decreased hypothalamic leptin actions. Additional hepatic LepR deficiency reverses these metabolic phenotypes. Thus, decreased hepatic insulin action suppresses hypothalamic leptin action with increased liver-derived soluble LepR. Human hepatic and circulating LepR levels also correlate negatively with hepatic insulin action indices. In mice, food restriction decreases hepatic insulin action and energy expenditure with increased circulating LepR. Hepatic LepR deficiency increases mortality with enhanced energy expenditure during food restriction. The liver translates metabolic cues regarding energy-deficient status, which is reflected by decreased hepatic insulin action, into soluble LepR, thereby suppressing energy dissipation and assuring survival during food shortages.

Insulin-like growth factor-1 levels are associated with high comorbidity of metabolic disorders in obese subjects; a Japanese single-center, retrospective-study.

Insulin like growth factor-1 (IGF-1) plays important roles in metabolic functions, especially in adulthood. Additionally, obese subjects are reportedly predisposed to having low absolute IGF-1 levels. However, the prevalence and clinical characteristics of obese subjects with low IGF-1 levels are unknown. We examined 64 obese subjects with a body mass index (BMI) ≥ 35 kg/m2, with no history of endocrinological disorders, receiving inpatient care. IGF-1 levels were interpreted based on the IGF-1 standard deviation score (SDS) clinically used and standardized by age and sex (low IGF-1 group; ≤ - 2.0 SDS and standard IGF-1 group; - 2.0 < and < + 2.0 SDS). Notably, 26.6% of the subjects had low IGF-1. Body fat mass and percentage, but not BMI, were significantly higher in the low than in the standard IGF-1 group. Furthermore, natural log-transformed high-sensitivity C-reactive protein, and the frequencies of dyslipidemia and hyperuricemia were higher in the low IGF-1 group. Moreover, among the subjects without diabetes, fasting glucose levels were significantly higher in the low IGF-1 group. Stepwise variable selection procedure revealed body fat percentage to be a parameter most strongly associated with low IGF-1. Thus, low IGF-1 levels may be an important marker of adiposity-associated metabolic disorders in obese patients.

Roles of FoxM1-driven basal ß-cell proliferation in maintenance of ß-cell mass and glucose tolerance during adulthood.

AIMS/INTRODUCTION: Whether basal ß-cell proliferation during adulthood is involved in maintaining sufficient ß-cell mass, and if so, the molecular mechanism(s) underlying basal ß-cell proliferation remain unclear. FoxM1 is a critical transcription factor which is known to play roles in 'adaptive' ß-cell proliferation, which facilitates rapid increases in ß-cell mass in response to increased insulin demands. Therefore, herein we focused on the roles of ß-cell FoxM1 in 'basal' ß-cell proliferation under normal conditions and in the maintenance of sufficient ß-cell mass as well as glucose homeostasis during adulthood. MATERIALS AND METHODS: FoxM1 deficiency was induced specifically in ß-cells of 8-week-old mice, followed by analyzing its short- (2 weeks) and long- (10 months) term effects on ß-cell proliferation, ß-cell mass, and glucose tolerance. RESULTS: FoxM1 deficiency suppressed ß-cell proliferation at both ages, indicating critical roles of FoxM1 in basal ß-cell proliferation throughout adulthood. While short-term FoxM1 deficiency affected neither ß-cell mass nor glucose tolerance, long-term FoxM1 deficiency suppressed ß-cell mass increases with impaired insulin secretion, thereby worsening glucose tolerance. In contrast, the insulin secretory function was not impaired in islets isolated from mice subjected to long-term ß-cell FoxM1 deficiency. Therefore, ß-cell mass reduction is the primary cause of impaired insulin secretion and deterioration of glucose tolerance due to long-term ß-cell FoxM1 deficiency. CONCLUSIONS: Basal low-level proliferation of ß-cells during adulthood is important for maintaining sufficient ß-cell mass and good glucose tolerance and ß-cell FoxM1 underlies this mechanism. Preserving ß-cell FoxM1 activity may prevent the impairment of glucose tolerance with advancing age.

Mutant GNAS detected in duodenal collections of secretin-stimulated pancreatic juice indicates the presence or emergence of pancreatic cysts.

OBJECTIVE: Pancreatic cysts are commonly detected in patients undergoing pancreatic imaging. Better approaches are needed to characterise these lesions. In this study we evaluated the utility of detecting mutant DNA in secretin-stimulated pancreatic juice. DESIGN: Secretin-stimulated pancreatic juice was collected from the duodenum of 291 subjects enrolled in Cancer of the Pancreas Screening trials at five US academic medical centres. The study population included subjects with a familial predisposition to pancreatic cancer who underwent pancreatic screening, and disease controls with normal pancreata, chronic pancreatitis, sporadic intraductal papillary mucinous neoplasm (IPMN) or other neoplasms. Somatic GNAS mutations (reported prevalence ≈ 66% of IPMNs) were measured using digital high-resolution melt-curve analysis and pyrosequencing. RESULTS: GNAS mutations were detected in secretin-stimulated pancreatic juice samples of 50 of 78 familial and sporadic cases of IPMN(s) (64.1%), 15 of 33 (45.5%) with only diminutive cysts (<5 mm), but none of 57 disease controls. GNAS mutations were also detected in five of 123 screened subjects without a pancreatic cyst. Among 97 subjects who had serial pancreatic evaluations, GNAS mutations detected in baseline juice samples predicted subsequent emergence or increasing size of pancreatic cysts. CONCLUSION: Duodenal collections of secretin-stimulated pancreatic juice from patients with IPMNs have a similar prevalence of mutant GNAS to primary IPMNs, indicating that these samples are an excellent source of mutant DNA from the pancreas. The detection of GNAS mutations before an IPMN is visible suggests that analysis of pancreatic juice has the potential to help in the risk stratification and surveillance of patients undergoing pancreatic screening.