Effects of high-dose oral insulin on immune responses in children at high risk for type 1 diabetes: the Pre-POINT randomized clinical trial.

IMPORTANCE: Exposing the oral mucosa to antigen may stimulate immune tolerance. It is unknown whether treatment with oral insulin can induce a tolerogenic immune response in children genetically susceptible to type 1 diabetes. OBJECTIVE: To assess the immune responses and adverse events associated with orally administered insulin in autoantibody-negative, genetically at-risk children. DESIGN, SETTING, AND PARTICIPANTS: The Pre-POINT study, a double-blind, placebo-controlled, dose-escalation, phase 1/2 clinical pilot study performed between 2009 and 2013 in Germany, Austria, the United States, and the United Kingdom and enrolling 25 islet autoantibody-negative children aged 2 to 7 years with a family history of type 1 diabetes and susceptible human leukocyte antigen class II genotypes. Follow-up was completed in August 2013. INTERVENTIONS: Children were randomized to receive oral insulin (n = 15) or placebo (n = 10) once daily for 3 to 18 months. Nine children received insulin with dose escalations from 2.5 to 7.5 mg (n = 3), 2.5 to 22.5 mg (n = 3), or 7.5 to 67.5 mg (n = 3) after 6 months; 6 children only received doses of 22.5 mg (n = 3) or 67.5 mg (n = 3). MAIN OUTCOMES AND MEASURES: An immune response to insulin, measured as serum IgG and saliva IgA binding to insulin, and CD4+ T-cell proliferative responses to insulin. RESULTS: Increases in IgG binding to insulin, saliva IgA binding to insulin, or CD4+ T-cell proliferative responses to insulin were observed in 2 of 10 (20% [95% CI, 0.1%-45%]) placebo-treated children and in 1 of 6 (16.7% [95% CI, 0.1%-46%]) children treated with 2.5 mg of insulin, 1 of 6 (16.7%[ 95% CI, 0.1%-46%]) treated with 7.5 mg, 2 of 6 (33.3% [95% CI, 0.1%-71%]) treated with 22.5 mg, and 5 of 6 (83.3% [ 95% CI, 53%-99.9%]) treated with 67.5 mg (P = .02). Insulin-responsive T cells displayed regulatory T-cell features after oral insulin treatment. No hypoglycemia, IgE responses to insulin, autoantibodies to glutamic acid decarboxylase or insulinoma-associated antigen 2, or diabetes were observed. Adverse events were reported in 12 insulin-treated children (67 events) and 10 placebo-treated children (35 events). CONCLUSIONS AND RELEVANCE: In this pilot study of children at high risk for type 1 diabetes, daily oral administration of 67.5 mg of insulin, compared with placebo, resulted in an immune response without hypoglycemia. These findings support the need for a phase 3 trial to determine whether oral insulin can prevent islet autoimmunity and diabetes in such children. TRIAL REGISTRATION: isrctn.org Identifier: ISRCTN76104595.

Effect of a single autologous cord blood infusion on beta-cell and immune function in children with new onset type 1 diabetes: a non-randomized, controlled trial.

BACKGROUND: The application of autologous cord blood in children with type 1 diabetes has been found to be safe, but not to preserve beta-cell function in a previous study, which, however, had not included a control group. OBJECTIVE: To compare the changes of metabolic and immune function over time between cord blood infused children and natural controls. SUBJECTS AND METHODS: Seven children with newly diagnosed type 1 diabetes underwent a single autologous cord blood infusion and 10 children were enrolled as natural controls in a non-randomized, controlled, open label intervention trial. Primary analyses were performed 1 year following cord blood infusion. Cases and controls were compared regarding metabolic [area under the curve (AUC) and peak C-peptide, insulin use, and HbA1c] and immune outcome (islet autoantibody titer and T-cell response), adjusted for age, gender, diabetes duration, and baseline levels. RESULTS: There were no significant adverse events related to the infusion. Metabolic and immune outcomes were not significantly different at 12 months follow-up between infused children and controls (e.g., adjusted p = 0.244 for AUC C-peptide, adjusted p = 0.820 for insulin use, adjusted p = 0.772 for peripheral regulatory T cells). Six-month change of AUC C-peptide correlated significantly with the number of infused CD34+ cells (r = 0.931, p = 0.002). CONCLUSIONS: An autologous cord blood infusion does not change the natural course of metabolic and immune parameters after disease onset. However, the content of CD34+ cells in the stored blood sample might offer potential for improvement of future cell therapies.

Does diabetes appear in distinct phenotypes in young people? Results of the diabetes mellitus incidence Cohort Registry (DiMelli).

INTRODUCTION: The diabetes mellitus Incidence Cohort Registry (DiMelli) aims to characterize diabetes phenotypes by immunologic, metabolic, and genetic markers. We classified patients into three groups according to islet autoantibody status and examined whether patients with multiple diabetes-associated autoantibodies, one autoantibody, or without autoantibodies differed with respect to clinical, metabolic, and genetic parameters, including an insulin sensitivity (IS) score based on waist, HbA1c, and triglycerides. We also assessed whether metabolic markers predicted the immune status. MATERIALS AND METHODS: As of June 2012, 630 patients in Bavaria, Germany, aged <20 years diagnosed with any type of diabetes within the preceding 6 months were registered in DiMelli. We compared the clinical and laboratory parameters between islet autoantibody status defined patient groups. Parameters showing the strongest associations were included in principal component analysis. Receiver operating characteristic curves were used to assess the ability of the IS Score to predict islet autoantibody status. RESULTS: Patients with multiple islet autoantibodies, one autoantibody, or without autoantibodies were significantly different in terms of BMI percentile, weight loss before diagnosis, fasting C-peptide (all, P<0.001), and IS Score (P=0.034). However, principal component analysis revealed no distinct patterns according to autoantibody status. At the optimal IS Score cut-off for predicting islet autoantibody positivity (single compared to none), the specificity was 52.0% and the sensitivity was 86.8%. With respect to prediction of multiple autoantibodies (compared to none), specificity and sensitivity were slightly lower and in combination inferior to those obtained using the BMI percentile and fasting C-peptide. DISCUSSION: The DiMelli study indicated that patients with and without islet autoantibodies differed with respect to metabolic and genetic markers but there was considerable overlap of phenotypes, and autoantibody status could not be predicted by these parameters. Thus, our results suggest that refined diabetes classification may require both immune and metabolic phenotyping.

No non-redundant function of suppressor of cytokine signaling 2 in insulin producing ß-cells.

The members of the Suppressor of Cytokine Signaling (SOCS) protein family mainly modulate the Janus kinase (JAK)/signal transducer and activator of transcription (STAT) pathway. SOCS-1 and SOCS-3 have already been shown to influence growth and apoptosis of pancreatic beta cells. We hypothesized that SOCS-2, which is expressed in pancreatic islets, also contributes to ß-cell physiology. We tested this hypothesis in vivo in SOCS-2-/- knockout mice and in vitro in Ins-1E rat insulinoma cells. We found that SOCS-2-/- mice have normal islet insulin secretion and unchanged glucose and insulin tolerance compared to wildtype controls. SOCS-2-/- are bigger than wildtype mice but body weight-corrected ß-cell mass and islet morphology were normal. Growth hormone-induced proliferation of Ins-1E cells was not affected by either siRNA-mediated SOCS-2 knockdown or stable SOCS-2 overexpression. Interleukin-1ß mediated cell death in vitro was unchanged after SOCS-2 knockdown. Similarly, autoimmune destruction of beta cells in vivo after multiple low-dose injections of streptozotocin (STZ) was not altered in SOCS-2-/- mice. In summary, SOCS-2-/- knockout mice have a normal function of insulin-producing pancreatic ß-cells, a fully adapted beta cell mass and a normal morphology of the endocrine islets. Based on in vitro evidence, the increased ß-cell mass in the mutants is likely due to indirect adaptive mechanisms and not the result of altered growth hormone signaling within the ß-cells. Immune mediated ß-cell destruction is also not affected by SOCS-2 ablation in vitro and in vivo.

Relative roles of the different Pax6 domains for pancreatic alpha cell development.

BACKGROUND: The transcription factor Pax6 functions in the specification and maintenance of the differentiated cell lineages in the endocrine pancreas. It has two DNA binding domains, the paired domain and the homeodomain, in addition to a C-terminal transactivation domain. The phenotype of Pax6-/- knockout mice suggests non-redundant functions of the transcription factor in the development of glucagon-expressing alpha-cells as this cell type is absent in the mutants. We ask the question of how the differentiation of pancreatic endocrine cells, in particular that of alpha-cells, is affected by selective inactivation of either one of the three major domains of Pax6. RESULTS: The Pax6Aey18 mutant mouse line, in which the paired domain is inactivated, showed a phenotype similar to that of Pax6-/- knockout mice with a near complete absence of glucagon-positive alpha-cells (0-4 cells/section; < or =1% of wt), reduced beta-cell area (74% of wt) and disorganized islets. The proportion of ghrelin-positive epsilon-cells was expanded. In Pax6Sey-Neu mutants, which lack the transactivation domain, alpha-and beta-cells where reduced to 25 and 40% of wt, respectively. We also studied two mouse lines with mutations in the homeodomain, Pax64Neu and Pax6132-14Neu. Neighboring amino acids are affected in the two lines and both point mutations abolish DNA binding of the classical P3 homeodomain target sequence. The pancreatic phenotype of the two mutants however was divergent. While Pax64Neu homozygotes showed a reduction of alpha- and beta-cells to 59 and 61%, respectively, pancreatic endocrine development was unaltered in the Pax6132-14Neu mutant strain. CONCLUSIONS: We show that inactivation of the Pax6 paired domain leads to a more severe phenotype with regards to the differentiation of pancreatic alpha-cells than the loss of the transactivation domain. The analysis of two different homeodomain mutants suggests that the binding of Pax6 to P3 homeodomain consensus sequences is not required for alpha-cell development. It rather seems that the homeodomain has a modulating role in Pax6 function, possibly by facilitating a PH0-like binding confirmation on paired domain target genes like proglucagon. This function is differentially affected by the two homeodomain mutations analyzed in this study.