Islet Autoimmunity in Adults With Impaired Glucose Tolerance and Recently Diagnosed, Treatment Naïve Type 2 Diabetes in the Restoring Insulin SEcretion (RISE) Study.

The presence of islet autoantibodies and islet reactive T cells (T+) in adults with established type 2 diabetes (T2D) have been shown to identify those patients with more severe ß-cell dysfunction. However, at what stage in the progression toward clinical T2D does islet autoimmunity emerge as an important component influencing ß-cell dysfunction? In this ancillary study to the Restoring Insulin SEcretion (RISE) Study, we investigated the prevalence of and association with ß-cell dysfunction of T+ and autoantibodies to the 65 kDa glutamic acid decarboxylase antigen (GADA) in obese pre-diabetes adults with impaired glucose tolerance (IGT) and recently diagnosed treatment naïve (Ndx) T2D. We further investigated the effect of 12 months of RISE interventions (metformin or liraglutide plus metformin, or with 3 months of insulin glargine followed by 9 months of metformin or placebo) on islet autoimmune reactivity. We observed GADA(+) in 1.6% of NdxT2D and 4.6% of IGT at baseline, and in 1.6% of NdxT2D and 5.3% of IGT at 12 months, but no significant associations between GADA(+) and ß-cell function. T(+) was observed in 50% of NdxT2D and 60.4% of IGT at baseline, and in 68.4% of NdxT2D and 83.9% of IGT at 12 months. T(+) NdxT2D were observed to have significantly higher fasting glucose (p = 0.004), and 2 h glucose (p = 0.0032), but significantly lower steady state C-peptide (sscpep, p = 0.007) compared to T(-) NdxT2D. T(+) IGT participants demonstrated lower but not significant (p = 0.025) acute (first phase) C-peptide response to glucose (ACPRg) compared to T(-) IGT. With metformin treatment, T(+) participants were observed to have a significantly lower Hemoglobin A1c (HbA1c, p = 0.002) and fasting C-peptide (p = 0.002) compared to T(-), whereas T(+) treated with liraglutide + metformin had significantly lower sscpep (p = 0.010) compared to T(-) participants. In the placebo group, T(+) participants demonstrated significantly lower ACPRg (p = 0.001) compared to T(-) participants. In summary, T(+) were found in a large percentage of obese pre-diabetes adults with IGT and in recently diagnosed T2D. Moreover, T(+) were significantly correlated with treatment effects and ß-cell dysfunction. Our results demonstrate that T(+) are an important component in T2D.

Setting the Stage for Islet Autoimmunity in Type 2 Diabetes: Obesity-Associated Chronic Systemic Inflammation and Endoplasmic Reticulum (ER) Stress.

Islet autoimmunity has been identified as a component of both type 1 (T1D) and type 2 (T2D) diabetes, but the pathway through which islet autoimmunity develops in T1D and T2D may be different. Acknowledging the presence of islet autoimmunity in the pathophysiology of T2D, a historically nonautoimmune metabolic disease, would pave the way for important changes in classifications of and therapeutic options for T2D. In order to fully appreciate the importance of islet autoimmunity in T2D, the underlying mechanisms for immune system activation need to be explored. In this review, we focus on the potential origin of immune system activation (innate and adaptive) leading to the development of islet autoimmunity in T2D.

Impact of islet autoimmunity on the progressive ß-cell functional decline in type 2 diabetes.

OBJECTIVE: Cross-sectional studies have suggested that islet autoimmunity may be more prevalent in type 2 diabetes (T2D) than previously appreciated and may contribute to the progressive decline in ß-cell function. In this study, we longitudinally evaluated the effect of islet autoimmune development on the progressive ß-cell dysfunction in T2D patients. RESEARCH DESIGN AND METHODS: Twenty-three T2D patients negative for islet autoantibodies (GAD antibody and insulinoma-associated protein 2) and islet-specific T cells were evaluated prospectively for up to 36 months. We investigated the percentage of patients who developed islet autoantibodies (Ab+) and/or islet-reactive T cells (T+) and the effect of the islet autoimmunity on fasting and glucagon-stimulated C-peptide responses. We defined positive islet autoimmunity as Ab+ and/or T+ for at least two study visits. RESULTS: Of the 23 patients, 6 (26%) remained negative for islet autoimmunity (Ab-T-), 14 (61%) developed Ab+ and/or T+, and 3 (13%) were unclassifiable because they developed islet autoimmunity at only one study visit. Islet Ab+ was observed to be less stable than islet-specific T-cell responses. Development of islet autoimmunity was significantly associated with a more rapid decline in fasting (P < 0.0001) and glucagon-stimulated (P < 0.05) C-peptide responses. CONCLUSIONS: These pilot data suggest that the development of islet autoimmunity in T2D is associated with a significantly more rapid ß-cell functional decline.

Islet-specific T-cell responses and proinflammatory monocytes define subtypes of autoantibody-negative ketosis-prone diabetes.

OBJECTIVE: Ketosis-prone diabetes (KPD) is characterized by diabetic ketoacidosis (DKA) in patients lacking typical features of type 1 diabetes. A validated classification scheme for KPD includes two autoantibody-negative ("A-") phenotypic forms: "A-ß-" (lean, early onset, lacking ß-cell functional reserve) and "A-ß+" (obese, late onset, with substantial ß-cell functional reserve after the index episode of DKA). Recent longitudinal analysis of a large KPD cohort revealed that the A-ß+ phenotype includes two distinct subtypes distinguished by the index DKA episode having a defined precipitant ("provoked," with progressive ß-cell function loss over time) or no precipitant ("unprovoked," with sustained ß-cell functional reserve). These three A- KPD subtypes are characterized by absence of humoral islet autoimmune markers, but a role for cellular islet autoimmunity is unknown. RESEARCH DESIGN AND METHODS: Islet-specific T-cell responses and the percentage of proinflammatory (CD14+CD16+) blood monocytes were measured in A-ß- (n = 7), provoked A-ß+ (n = 15), and unprovoked A-ß+ (n = 13) KPD patients. Genotyping was performed for type 1 diabetes-associated HLA class II alleles. RESULTS: Provoked A-ß+ and A-ß- KPD patients manifested stronger islet-specific T-cell responses (P < 0.03) and higher percentages of proinflammatory CD14+CD16+ monocytes (P < 0.01) than unprovoked A-ß+ KPD patients. A significant relationship between type 1 diabetes HLA class II protective alleles and negative T-cell responses was observed. CONCLUSIONS: Provoked A-ß+ KPD and A-ß- KPD are associated with a high frequency of cellular islet autoimmunity and proinflammatory monocyte populations. In contrast, unprovoked A-ß+ KPD lacks both humoral and cellular islet autoimmunity.

Identification of autoantibody-negative autoimmune type 2 diabetic patients.

OBJECTIVE: Islet autoimmunity has long been recognized in the pathogenesis of type 1 diabetes and is becoming increasingly acknowledged as a component in the pathogenesis of type 2 diabetes. Islet reactive T cells and autoantibodies have been demonstrated in type 1 diabetes, whereas islet autoimmunity in type 2 diabetes has been limited to islet autoantibodies. In this study, we investigated whether islet reactive T cells might also be present in type 2 diabetic patients and how islet reactive T cells correlate with ß-cell function. RESEARCH DESIGN AND METHODS: Adult phenotypic type 2 diabetic patients (n = 36) were screened for islet reactive T-cell responses using cellular immunoblotting and five islet autoantibodies (islet cell antibody, GADA, insulin autoantibody, insulinoma-associated protein-2 autoantibody, and zinc transporter autoantibody). RESULTS: We identified four subgroups of adult phenotypic type 2 diabetic patients based on their immunological status (Ab(-)T(-), Ab(+)T(-), Ab(-)T(+), and Ab(+)T(+)). The Ab(-)T(+) type 2 diabetic patients demonstrated T-cell responses similar to those of the Ab(+)T(+) type 2 diabetic patients. Data were adjusted for BMI, insulin resistance, and duration of diabetes. Significant differences (P < 0.02) were observed among groups for fasting and glucagon-stimulated C-peptide responses. T-cell responses to islet proteins were also demonstrated to fluctuate less than autoantibody responses. CONCLUSIONS: We have identified a group of adult autoimmune phenotypic type 2 diabetic patients who are Ab(-)T(+) and thus would not be detected using autoantibody testing alone. We conclude that islet autoimmunity may be more prevalent in adult phenotypic type 2 diabetic patients than previously estimated.

Latent autoimmune diabetes in adults.

CONTEXT: Autoantibodies that are reactive to islet antigens are present at the time of diagnosis in most patients with type 1 diabetes. Additionally, approximately 10% of phenotypic type 2 diabetic patients are positive for at least one of the islet autoantibodies, and this group is often referred to as "latent autoimmune diabetes in adults (LADA)." These patients share many genetic and immunological similarities with type 1 diabetes, suggesting that LADA, like type 1 diabetes, is an autoimmune disease. However, there are differences in autoantibody clustering, T cell reactivity, and genetic susceptibility and protection between type 1 diabetes and LADA, implying important differences in the underlying disease processes. EVIDENCE ACQUISITION AND SYNTHESIS: In this clinical review, we will summarize the current understanding of LADA based on the MEDLINE search of all peer-reviewed publications (original articles and reviews) on this topic between 1974 and 2009. CONCLUSIONS: In LADA, diabetes occurs earlier in the beta-cell-destructive process because of the greater insulin resistance. Complexities arise also because of variable definitions of LADA and type 1 diabetes in adults. As immunomodulatory therapies that slow or halt the type 1 diabetes disease process are discovered, testing these therapies in LADA will be essential.

Is latent autoimmune diabetes in adults distinct from type 1 diabetes or just type 1 diabetes at an older age?

Diabetes is classified clinically into two types: type 1 and type 2 diabetes. Type 1 diabetes is an autoimmune diabetes, whereas, in contrast, type 2 diabetes is nonautoimmune. However, there is a group of phenotypic adult type 2 diabetic patients ( approximately 10%) who have islet autoantibodies similar to type 1 diabetes. These patients are said to have latent autoimmune diabetes in adults (LADA) or type 1.5 diabetes. T-cells reacting with islet proteins have been demonstrated in type 1 and type 1.5 diabetic patients. In contrast, classic autoantibody-negative type 2 diabetic patients are also negative for T-cell responses to islet proteins. Therefore, we questioned whether type 1 and type 1.5 diabetes are similar or different autoimmune diseases. We have investigated the immunological and metabolic differences between type 1, type 1.5, and classic type 2 diabetic patients. We have identified autoantibody differences, differences in islet proteins recognized by T-cells, and differences in insulin resistance. We have also identified a small group of patients who have T-cells responsive to islet proteins but who are autoantibody negative. These patients appear to be similar to type 1.5 patients in having decreased stimulated C-peptide values. These immunological differences between type 1 and type 1.5 diabetes suggest at least partially distinct disease processes.

Autoimmunity and clinical course in children with type 1, type 2, and type 1.5 diabetes.

AIMS: Both type 1 (T1D) and type 2 diabetes (T2D) are increasing in incidence in children; often an admixture of T1D and T2D features are present at diagnosis. We examined the relationship between diabetes autoantibodies (DAA), human leukocyte antigen (HLA), and clinical course in subjects grouped by clinical diabetes type. METHODS: Subjects 8-18 years old with T1D, T2D, and mixed clinical features (T1.5D), were studied at diagnosis. DAA were measured in all subjects; a subset of subjects underwent HLA genotyping. Clinical course was followed in 84% of subjects for 47.9+8.7 months. RESULTS: Eighty-nine percent of T1.5D subjects were positive for at least one DAA; 88% of HLA-typed subjects had risk HLA genotypes. Two subjects initially treated with oral agents were subsequently treated with insulin (50%); one had risk HLA, and the other was DAA positive. Thirty-three percent of T2D subjects were DAA positive and 93% were treated with oral agents at diagnosis. Three subjects were subsequently treated with insulin (21%); of these, two were DAA positive, and one had risk HLA. No subject who remained on diet therapy or oral agents had a combination of DAA-positivity and risk HLA genotype. CONCLUSIONS: Children clinically classified with T1.5D or T2D have a high frequency of autoimmune markers and T1D-associated HLA alleles which appears to indicate a more aggressive diabetes disease process, as has been shown for DAA-positive adults with phenotypic T2D.

Autoimmunity to islet proteins in children diagnosed with new-onset diabetes.

Autoantibody and T cells reacting with islet proteins have been demonstrated in patients with type 1 diabetes. In recent years an increasing number of children have been clinically classified with type 2 (not ketosis prone, evidence of insulin resistance, presence of acanthosis nigricans, and obesity) or indeterminant diabetes (admixture of clinical features of types 1 and 2). In this study, we compared the islet cell autoantibody and T-cell responses to islet proteins in type 2 (n = 19) and indeterminant (n = 16) children (<18 yr of age) to classic type 1 (n = 37) diabetic patients. We observed that 37 of 37 type 1 diabetic children demonstrated autoantibody and/or T-cell reactivity to islet proteins. Fourteen of the 19 type 2 patients were positive for islet cell autoantibodies, and six of 14 were positive for T-cell responses to islet proteins. For the indeterminant patients, 11 of 16 of the patients were positive for autoantibodies, and six of 16 patients were positive for T-cell responses to islet proteins. These results demonstrate that autoimmunity to islet proteins is present in a high percentage of children classified as indeterminant or type 2 diabetes. Moreover, the presence of obesity or acanthosis nigracans does not reliably distinguish children with or without islet cell autoimmunity.