Feasibility of overnight closed-loop therapy in young children with type 1 diabetes aged 3-6 years: comparison between diluted and standard insulin strength.

OBJECTIVE: To assess feasibility of overnight closed-loop therapy in young children with type 1 diabetes and contrast closed loop using diluted versus standard insulin strength. RESEARCH DESIGN AND METHODS: Eleven children (male 6; age range 3.75-6.96 years; glycated hemoglobin 60 (14) mmol/mol; body mass index SD score 1.0 (0.8); diabetes duration 2.2 (1.0) years, mean (SD); total daily dose 12.9 (10.6, 16.5) IU/day, median (IQR)) were studied at a clinical research facility on two occasions. In random order, participants received closed loop with diluted insulin aspart (CL_Dil; 20 IU/mL) or closed loop with standard aspart (CL_Std; 100 IU/mL) from 17:00 until 8:00 the following morning. Children consumed an evening meal at 17:00 (44 (12) gCHO) and an optional bedtime snack (6 (7) gCHO) identical on both occasions. Meal insulin boluses were calculated by standard pump bolus calculators. Basal rates on insulin pump were adjusted every 15 min as directed by a model-predictive-control algorithm informed by a real-time glucose sensor values. RESULTS: Mean plasma glucose was 122 (24) mg/dL during CL_Dil vs 122 (23) mg/dL during CL_Std (p=0.993). The time spent in the target glucose range 70-145 mg/dL was 83 (70, 100)% vs 72 (54, 81)% (p=0.328). Time above 145 mg/dL was 13 (0, 27)% vs 19 (10, 45)% (p=0.477) and time spent below 70 mg/dL was 0.0 (0.0, 1.4)% vs 1.4 (0.0, 11.6)% (p=0.161). One asymptomatic hypoglycemia below 63 mg/dL occurred in one participant during CL_Dil versus six episodes in five participants during CL_Std (p=0.09). Glucose variability measured by CV of plasma glucose tended to be reduced during CL_Dil (20% (13, 31) vs 32% (24, 42), p=0.075). CONCLUSIONS: In this feasibility study, closed-loop therapy maintained good overnight glucose control with tendency towards reduced hypoglycemia and reduced glucose variability using diluted insulin. TRIAL REGISTRATION NUMBER: clinicaltrials.gov Identifier: NCT01557634.This work was funded by the Juvenile Diabetes Research Foundation (JDRF Grant Number: 22-2011-668) and supported by NIHR Cambridge Biomedical Research Centre.This is the final published version. It first appeared at http://drc.bmj.com/content/2/1/e000040.abstract

Overnight closed-loop insulin delivery in young people with type 1 diabetes: a free-living, randomized clinical trial.

OBJECTIVE: To evaluate feasibility, safety, and efficacy of overnight closed-loop insulin delivery in free-living youth with type 1 diabetes. RESEARCH DESIGN AND METHODS: Overnight closed loop was evaluated at home by 16 pump-treated adolescents with type 1 diabetes aged 12-18 years. Over a 3-week period, overnight insulin delivery was directed by a closed-loop system, and on another 3-week period sensor-augmented therapy was applied. The order of interventions was random. The primary end point was time when adjusted sensor glucose was between 3.9 and 8.0 mmol/L from 2300 to 0700 h. RESULTS: Closed loop was constantly applied over at least 4 h on 269 nights (80%); sensor data were collected over at least 4 h on 282 control nights (84%). Closed loop increased time spent with glucose in target by a median 15% (interquartile range -9 to 43; P < 0.001). Mean overnight glucose was reduced by a mean 14 (SD 58) mg/dL (P < 0.001). Time when glucose was <70 mg/dL was low in both groups, but nights with glucose <63 mg/dL for at least 20 min were less frequent during closed loop (10 vs. 17%; P = 0.01). Despite lower total daily insulin doses by a median 2.3 (interquartile range -4.7 to 9.3) units (P = 0.009), overall 24-h glucose was reduced by a mean 9 (SD 41) mg/dL (P = 0.006) during closed loop. CONCLUSIONS: Unsupervised home use of overnight closed loop in adolescents with type 1 diabetes is safe and feasible. Glucose control was improved during the day and night with fewer episodes of nocturnal hypoglycemia.Supported by Juvenile Diabetes Research Foundation (#22-2006-1113, #22-2007-1801, #22-2009-801, #22-2009-802), Diabetes UK (BDA07/0003549), National Institute of Diabetes and Digestive and Kidney Diseases (1R01DK085621), Medical Research Council Centre for Obesity and Related metabolic Diseases, and National Institute for Health Research Cambridge Biomedical Research Centre. Abbott Diabetes Care supplied continuous glucose delivery devices and sensors and modified devices to facilitate real-time connectivity.This is the final published version, also available from the American Diabetes Association at http://care.diabetesjournals.org/content/37/5/1204

Analysis of LIN28A in early human ovary development and as a candidate gene for primary ovarian insufficiency

Lin28 proteins are emerging as important regulators of microRNAs in endocrine systems. Lin28a regulates primordial germ cell development and puberty timing in mice, whereas the related protein LIN28B is associated with age at menarche in genome-wide association studies in humans. Here, we studied expression of LIN28A and LIN28B in early human gonad development. LIN28A increased in the developing ovary between 6 and 9 weeks post conception, but not in the developing testis. Immunohistochemistry demonstrated LIN28A in peripheral germ cells. LIN28B was expressed at lower levels in both tissues and did not increase with time. As disruption of Lin28a affects germ cell development in mice, LIN28A was considered a candidate gene for primary ovarian insufficiency (POI) in humans. However, no significant changes were found in 50 women studied. These findings show LIN28A is strongly expressed in germ cells during early human ovary development, but disruption of LIN28A is not a common cause of POI

The use of human pluripotent stem cells to model HNF1B-associated diabetes

Heterozygous mutations in the transcription factor, hepatocyte nuclear factor 1B (HNF1B), result in multisystem disease including diabetes due to beta-cell dysfunction and pancreatic hypoplasia. However, the mechanisms that underlie development of diabetes in HNF1B mutation carriers are still not fully understood due to lack of an appropriate model system. Human induced pluripotent stem cells (hiPSCs), which are capable of self-renewal and can differentiate into any cell type, provide an advantageous alternative to model human developmental diseases. The aim of this project was to develop a hiPSC based model system to determine the molecular mechanisms by which HNF1B mutations cause pancreatic hypoplasia and diabetes. HNF1B mutant hiPSC lines were produced using CRISPR-Cas9 genome editing. Isogenic HNF1B wild-type, homozygous and heterozygous mutant hiPSC lines were directed to differentiate along the pancreatic lineage and cells were phenotyped at each stage of the differentiation process to check for appropriate expression of lineage markers. The normal expression pattern of HNF1B in human pancreas development was analysed and showed up-regulation of HNF1B at the foregut stage, and during pancreas specification. Homozygous knockout of HNF1B resulted in failure of foregut and pancreatic progenitor development, while heterozygous knockout of HNF1B resulted in impairment of pancreatic progenitor and endocrine cell differentiation as well as impaired insulin secretion upon glucose stimulation. Cell proliferation analyses showed a significant decrease in the proliferation rate in HNF1B heterozygous and homozygous mutant cells compared with wild-type cells at the foregut stage while no change in the apoptosis rate could be detected. RNA-sequencing and ATAC-sequencing, were used to further define the molecular mechanisms controlled by HNF1B and the effect HNF1B on modulation of chromatin accessibility during pancreas development. These results provide further insights into the molecular mechanisms by which HNF1B regulates human pancreas development and function, revealing that HNF1B haploinsufficiency impairs the expansion and maintenance of pancreatic progenitor cells in vitro. In vivo, this would likely result in reduced beta cell numbers at birth and diabetes later in life in patients with HNF1B-associated disease. These mechanisms suggest that the capacity to produce pancreatic progenitor cells during embryonic life could determine individual susceptibility to diabetes. Wellcome Trust PhD Programme for Clinician

Modeling HNF1B-associated monogenic diabetes using human iPSCs reveals an early stage impairment of the pancreatic developmental program.

Heterozygous mutations in HNF1B in humans result in a multisystem disorder, including pancreatic hypoplasia and diabetes mellitus. Here we used a well-controlled human induced pluripotent stem cell pancreatic differentiation model to elucidate the molecular mechanisms underlying HNF1B-associated diabetes. Our results show that lack of HNF1B blocks specification of pancreatic fate from the foregut progenitor (FP) stage, but HNF1B haploinsufficiency allows differentiation of multipotent pancreatic progenitor cells (MPCs) and insulin-secreting β-like cells. We show that HNF1B haploinsufficiency impairs cell proliferation in FPs and MPCs. This could be attributed to impaired induction of key pancreatic developmental genes, including SOX11, ROBO2, and additional TEAD1 target genes whose function is associated with MPC self-renewal. In this work we uncover an exhaustive list of potential HNF1B gene targets during human pancreas organogenesis whose downregulation might underlie HNF1B-associated diabetes onset in humans, thus providing an important resource to understand the pathogenesis of this disease.We thank Prof. Andrew T. Hattersley (Institute of Biomedical and Clinical Science, University of Exeter Medical School, Exeter, UK) for important discussions orienting the study. S.A.R.-S. is a career investigator from the Consejo Nacional de Investigaciones Científicas y Técnicas of Argentina (CONICET). This work was supported by the CONICET/Royal Society International Exchanges Cost Share 2018 (IEC\R2\181023) to L.V. and S.A.R.-S. The S.A.R.-S. laboratory is funded by grants from Agencia Nacional de Promoción Científica y Tecnológica of Argentina (PICT-2015 3605, PICT-2017 2071) and the Universidad de Buenos Aires (UBACYT20020170200156BA). The L.V. laboratory is funded by the ERC advanced grant New-Chol, the core support grant from the Wellcome Trust and Medical Research Council of the Wellcome–MRC Cambridge Stem Cell Institute, and the Cambridge University Hospitals NIHR Biomedical Research Centre (BRC-1215-20014). The views expressed are those of the authors and not necessarily those of the NIHR or the Department of Health and Social Care. RHK was funded by the Cambridge Wellcome Trust PhD clinical program, CS by ASTAR studentship, PM, DM, SV, KT, MC by the Sanger Wellcome Institute. E.O. is supported by a PhD fellowship from the CONICET

GATA6 Cooperates with EOMES/SMAD2/3 to Deploy the Gene Regulatory Network Governing Human Definitive Endoderm and Pancreas Formation.

Heterozygous de novo mutations in GATA6 are the most frequent cause of pancreatic agenesis in humans. In mice, however, a similar phenotype requires the biallelic loss of Gata6 and its paralog Gata4. To elaborate the human-specific requirements for GATA6, we chose to model GATA6 loss in vitro by combining both gene-edited and patient-derived pluripotent stem cells (hPSC) and directed differentiation toward beta-like cells. We find that GATA6 heterozygous hPSC show a modest reduction in definitive endoderm (DE) formation, while GATA6 null hPSC fail to enter the DE lineage. Consistent with these results, genome-wide studies show that GATA6 binds and cooperates with EOMES/SMAD2/3 to regulate the expression of cardinal endoderm genes. The early deficit in DE is accompanied by a significant reduction in PDX1+ pancreatic progenitors and C-PEPTIDE+ beta-like cells. Taken together, our data position GATA6 as a gatekeeper to early human, but not murine, pancreatic ontogeny.We thank the NIHR Cambridge BRC hiPSC core facility for the derivation of GATA6 hiPSC lines, Dr. Norihiro Tsuneyoshi for advice and guidance on gene editing using TALENs, and Dr. Bruno Reversade for insightful discussions. This work was funded by an EDB Singapore Childhood Undiagnosed Diseases Program grant and an A*STAR Strategic Positioning Fund (SPF) Genetic Orphan Diseases Adopted: Fostering Innovation Therapy (GODAFIT) grant and by an ERC starting grant Relieve IMDs and core grant funding from the Wellcome Trust and Medical Research Council (PSAG028) (LV and PM). A.T.H. is a Wellcome Trust Senior Investigato

GATA6 Cooperates with EOMES/SMAD2/3 to Deploy the Gene Regulatory Network Governing Human Definitive Endoderm and Pancreas Formation.

Heterozygous de novo mutations in GATA6 are the most frequent cause of pancreatic agenesis in humans. In mice, however, a similar phenotype requires the biallelic loss of Gata6 and its paralog Gata4. To elaborate the human-specific requirements for GATA6, we chose to model GATA6 loss in vitro by combining both gene-edited and patient-derived pluripotent stem cells (hPSCs) and directed differentiation toward β-like cells. We find that GATA6 heterozygous hPSCs show a modest reduction in definitive endoderm (DE) formation, while GATA6-null hPSCs fail to enter the DE lineage. Consistent with these results, genome-wide studies show that GATA6 binds and cooperates with EOMES/SMAD2/3 to regulate the expression of cardinal endoderm genes. The early deficit in DE is accompanied by a significant reduction in PDX1+ pancreatic progenitors and C-PEPTIDE+ β-like cells. Taken together, our data position GATA6 as a gatekeeper to early human, but not murine, pancreatic ontogeny.We thank the NIHR Cambridge BRC hiPSC core facility for the derivation of GATA6 hiPSC lines, Dr. Norihiro Tsuneyoshi for advice and guidance on gene editing using TALENs, and Dr. Bruno Reversade for insightful discussions. This work was funded by an EDB Singapore Childhood Undiagnosed Diseases Program grant and an A*STAR Strategic Positioning Fund (SPF) Genetic Orphan Diseases Adopted: Fostering Innovation Therapy (GODAFIT) grant and by an ERC starting grant Relieve IMDs and core grant funding from the Wellcome Trust and Medical Research Council (PSAG028) (LV and PM). A.T.H. is a Wellcome Trust Senior Investigato