Metabolic parameters and adipokine profile during GH replacement therapy in children with GH deficiency

Objective: GH replacement therapy in children with GH deficiency (GHD) mainly promotes linear growth. Not only have very few studies fully analyzed the metabolic consequences of GH therapy, but also the question as to whether GH may affect adipokine secretion has been insufficiently investigated. Our aim was to study the effects of GH replacement therapy on auxological data, lipid and glycemic profiles, insulin homeostasis (HOMA-IR) and serum adipokines in children. Methods: This was a 1-year prospective study. Thirty-four GHD children (11.6G2.6 years) and thirty healthy matched controls were enrolled. Children affected by GHD were studied both before beginning continuous GH replacement therapy and again at 12 months. Results: At the beginning of the study, total and LDL cholesterol were higher in GHD children than in controls (P!0.001), whereas HDL cholesterol, triglycerides, insulin, HOMA-IR, leptin, and adiponectin were similar. At 12 months of continuous GH replacement therapy in the GHD group, there was a significant increase in both auxological data and IGF-I (P!0.001); total cholesterol (P!0.001), LDL (P!0.001), triglycerides (P!0.005), and leptin (P!0.001) decreased significantly; HDL (P!0.003), insulin (P!0.001), HOMA-IR (P!0.001) increased while adiponectin was unmodified. Furthermore, IGF-ID showed an inverse correlation with leptin D (rZK0.398, PZ0.02). Conclusions: In GHD children, the evaluation of metabolic parameters proves to be a useful tool for the evaluation of auxological parameters during GH replacement therapy. In our study, GH replacement therapy in GHD children improved final height, restored IGF-I levels, reduced leptin levels, and improved the lipid profile, without producing any unfavorable effects on glucose metabolism

Induction of mouse pancreatic ductal differentiation, an in vitro assay

Abstract Despite recent technical advances for studying lineage tracing and gene functions, our knowledge of pancreatic duct progenitor cells and mechanisms involved in their differentiation remains a huge void in our understanding of pancreatic development. A deeper insight into ductal differentiation is needed because ductal cells may harbor pancreatic stem/progenitor cells that could give rise to new islets. Also, since the most common pancreatic tumors form structures expressing ductal cell-specific markers, studies of ductal development may provide better markers for pancreatic tumor classification. One major longstanding problem in the study of pancreatic ductal differentiation has been the lack of an effective in vitro model. We thus wished to develop an in vitro system for the study of pancreatic duct development. In doing so, we have developed a specific culture condition to promote ductal differentiation of E11.5 pancreatic rudiments. Normally, pancreatic explants cultured in vitro develop to form endocrine, acinar, as well as ductal cells. Here, we report that addition of a combination of EGF, fibroblast growth factor-10, and platelet-derived growth factor-AA to the explant cultures promotes ductal differentiation, while preventing endocrine and acinar differentiation. This culture system for differentiation and enrichment of pancreatic ductal cells may allow identification of gene(s) involved in ductal development

In vitro generation of pancreatic endocrine cells from human adult fibroblast-like limbal stem cells

Stem cells might provide unlimited supply of transplantable cells for β-cell replacement therapy in diabetes. The human limbus is a highly specialized region hosting a well-recognized population of epithelial stem cells, which sustain the continuous renewal of the cornea, and the recently identified stromal fibroblast-like stem cells (f-LSCs), with apparent broader plasticity. However, the lack of specific molecular markers for the identification of the multipotent limbal subpopulation has so far limited the investigation of their differentiation potential. In this study we show that the human limbus contains uncommitted cells that could be potentially harnessed for the treatment of diabetes. Fourteen limbal biopsies were obtained from patients undergoing surgery for ocular diseases not involving the conjunctiva or corneal surface. We identified a subpopulation of f-LSCs characterized by robust proliferative capacity, expressing several pluripotent stem cell markers and exhibiting self-renewal ability. We then demonstrated the potential of f-LSCs to differentiate in vitro into functional insulin-secreting cells by developing a four-step differentiation protocol that efficiently directed f-LSCs towards the pancreatic endocrine cell fate. The expression of specific endodermal, pancreatic, islet, and β-cell markers, as well as functional properties of f-LSC-derived insulin-producing cells, were evaluated during differentiation. With our stage-specific approach, up to 77% of f-LSCs eventually differentiated into cells expressing insulin (also assessed as C-peptide) and exhibited phenotypic features of mature β-cells, such as expression of critical transcription factors and presence of secretory granules. Although insulin content was about 160-fold lower than what observed in adult islets, differentiated cells processed ∼98% of their proinsulin content, similar to mature β-cells. Moreover, they responded in vitro in a regulated manner to multiple secretory stimuli, including glucose. In conclusion, f-LSCs represent a possible relevant source of autologous, transplantable, insulin-producing cells that could be tested for the reversal of diabetes

MULTIPLE PLURIPOTENT STEM CELL MARKERS IN HUMAN ANAPLASTIC THYROID CANCER: THE PUTATIVE UPSTREAM ROLE OF SOX-2

Background: Anaplastic Thyroid Carcinoma (ATC) is a rare and aggressive endocrine tumor, with highly undifferentiated morphology. It has been suggested that cancer stem cells (CSCs) might play a central role in ATC. The objectives of this study were the following: 1) to characterize CSCs from ex vivo ATC specimens by investigating the expression of several pluripotent stem cell markers; 2) to evaluate in vitro drug resistance modifications after specific CSC transcription factor switch off. Methods: Ex vivo: eight formalin-fixed, paraffin-embedded ATC specimens were analyzed by RT and qRT-PCR and immunohistochemistry. In vitro: in ATC SW1736 cells the expression levels of OCT-4, NANOG and ABCG2 and the sensitivity to either cisplatin or doxorubicin were evaluated after silencing. Results: OCT-4, KLF4 and SOX2 transcription factors and C-KIT and THY-1 stem surface antigens showed variable up-regulation in all ATC cases. The SW1736 cell line was characterized by a high percentage of stem population (10.4 \ub1 2.1 % of cells were aldehyde dehydrogenase positive) and a high expression of several CSC markers (SOX2, OCT4, NANOG, C-MYC, SSEA4). SOX2 silencing down-regulated OCT-4, NANOG and ABCG2. SOX2 silencing sensitized SW1736 cells, causing a significant cell death increase (1.8 fold) in comparison to control cells with 10 \ub5M cisplatin (93.9\ub13.4% vs. 52.6\ub19.4%, p<0.01) and 2.7 fold with 0.5\ub5M doxorubicin (45.8\ub19.9% vs. 17.1\ub13.4% p<0.01). ABCG2 silencing caused increased cell death with both cisplatin (74.9\ub11.4%) and doxorubicin treatment (74.1\ub10.1%) vs. no-target-treated cells (respectively, 45.8\ub11.0% and 48.6\ub11.0%, p<0.001). Conclusions: The characterization of CSCs in ATC through the analysis of multiple pluripotent stem cell markers might be useful in identifying cells with a stem-like phenotype capable of resisting conventional chemotherapy. In addition, our data demonstrate that SOX2 switch-off through ABCG2 transporter down-regulation has a major role in overcoming CSC chemotherapy resistance

Visceral Adiposity Index: A reliable indicator of visceral fat function associated with cardiometabolic risk

Objective: To individuate a novel sex-specific index, based on Waist Circumference (WC), Body Mass Index (BMI), Triglycerides (TG) and HDL cholesterol (HDL), indirectly expressing visceral fat function. Research design and Methods: Visceral Adiposity Index (VAI) was first modelled on 315 non-obese healthy subjects. Using two multiple logistic regression models, VAI was retrospectively validated in 1,498 primary care patients in comparison to classical cardio and cerebrovascular risk factors. Results: All components of metabolic syndrome increased significantly across VAI quintiles. VAI was independently associated with both cardiovascular (OR:2.45; 95%CI: 1.52-3.95; p&lt;0.001) and cerebrovascular events (OR:1.63; 95%CI: 1.06-2.50; p=0.025). VAI also showed significant inverse correlation with insulin sensitivity during euglycemic-hyperinsulinemic clamp in a subgroup of patients (R(s)= -0.721; p&lt;0.001). By contrast, no correlations were found for WC and BMI. Conclusions: Our study suggests VAI is a valuable indicator of "visceral adipose function" and insulin sensitivity, and its increase is strongly associated with cardiometabolic risk

Recovery of Endogenous β-Cell Function in Nonhuman Primates After Chemical Diabetes Induction and Islet Transplantation

OBJECTIVE—To describe the ability of nonhuman primate endocrine pancreata to reestablish endogenous insulin production after chemical β-cell destruction

A Non-Invasive method of quantifying pancreatic volume in mice using micro-MRI

In experimental models of pancreatic growth and recovery, changes in pancreatic size are assessed by euthanizing a large cohort of animals at varying time points and measuring organ mass. However, to ascertain this information in clinical practice, patients with pancreatic disorders routinely undergo non-invasive cross-sectional imaging of the pancreas using magnetic resonance imaging (MRI) or computed tomography (CT). The aim of the current study was to develop a thinsliced, optimized sequence protocol using a high field MRI to accurately calculate pancreatic volumes in the most common experimental animal, the mouse. Using a 7 Telsa Bruker micro-MRI system, we performed abdominal imaging in whole-fixed mice in three standard planes: axial, sagittal, and coronal. The contour of the pancreas was traced using Vitrea software and then transformed into a 3-dimensional (3D) reconstruction, from which volumetric measurements were calculated. Images were optimized using heart perfusion-fixation, T1 sequence analysis, and 0.2 to 0.4 mm thick slices. As proof of principle, increases in pancreatic volume among mice of different ages correlated tightly with increasing body weight. In summary, this is the first study to measure pancreatic volumes in mice, using a high field 7 Tesla micro-MRI and a thin-sliced, optimized sequence protocol. We anticipate that micro-MRI will improve the ability to non-invasively quantify changes in pancreatic size and will dramatically reduce the number of animals required to serially assess pancreatic growth and recovery.© 2014 Paredes et al

In Vitro Phenotypic, Genomic and Proteomic Characterization of a Cytokine-Resistant Murine β-TC3 Cell Line

Type 1 diabetes mellitus (T1DM) is caused by the selective destruction of insulin-producing β-cells. This process is mediated by cells of the immune system through release of nitric oxide, free radicals and pro-inflammatory cytokines, which induce a complex network of intracellular signalling cascades, eventually affecting the expression of genes involved in β-cell survival