Intrauterine hyperglycemia is associated with an earlier diagnosis of diabetes in HNF-1alpha gene mutation carriers

OBJECTIVE: In animals, experimentally induced maternal hyperglycemia during pregnancy results in hyperglycemic offspring. Similarly, Pima Indian offspring with mothers who are diabetic at the time of pregnancy have increased risk of early-onset diabetes. We hypothesized that exposure to hyperglycemia in utero would decrease the age at diagnosis of diabetes in patients with maturity-onset diabetes of the young (MODY) due to a mutation in the hepatocyte nuclear factor 1alpha (HNF-1alpha) gene. RESEARCH DESIGN AND METHODS: We analyzed the affect of maternal diabetes on age at diagnosis of diabetes in 150 HNF-1alpha gene mutation carriers from 55 families. RESULTS: Age at diagnosis in HNF-1alpha mutation carriers was younger when the mother was diagnosed before pregnancy compared with when the mother was diagnosed after pregnancy (15.5 +/- 5.4 vs. 27.5 +/- 13.1 years, P < 0.0001). This is unlikely to represent a generalized familial decrease in age at diagnosis due to a more severe mutation, because no difference was seen in age of the offspring at diagnosis of diabetes when the father was diagnosed at a young age, and a similar trend was seen when only the single common mutation, P291fsinsC, was analyzed. CONCLUSIONS: We conclude that maternal hyperglycemia during pregnancy probably increases the penetrance of HNF-1alpha mutations. The potential role of exposure to hyperglycemia in utero in a monogenic diabetic subgroup warrants prospective study.     

Spectrum of HNF1A and GCK mutations in Canadian families with maturity-onset diabetes of the young (MODY)

PURPOSE: Maturity-onset diabetes of the young (MODY) is a subtype of type 2 diabetes characterized by autosomal-dominant inheritance and early onset. The pathophysiology of MODY is primarily defective insulin secretion resulting from mutations in at least 6 different genes. Most affected patients harbour mutations in either GCK (encoding glucokinase, also called MODY2) and HNF1A (encoding hepatic nuclear factor-1alpha, also called MODY3). We studied Canadian probands to determine if they had mutations in MODY2 or MODY3 genes. METHOD: We used genomic DNA sequencing of probands from 9 previously unreported Canadian MODY families. RESULTS: Five MODY probands had mutations in HNF1A, of which 4 were novel (namely IVS5-1delTAG, E275fsdelGAAG, F268S and L44fsdelC) and 4 had mutations in GCK, of which 2 were novel (E237K and L324P). These mutations expand the spectrum of MODY mutations and bring the total number of Canadian MODY families that have been molecularly defined in our laboratory to 15 (8 MODY3 and 7 MODY2). CONCLUSION: Because of the growing evidence that molecular diagnosis may affect prognosis and treatment, this information may be important in future for Canadian MODY families and their physicians.     

Genetic evidence that HNF-1alpha-dependent transcriptional control of HNF-4alpha is essential for human pancreatic beta cell function

Mutations in the genes encoding hepatocyte nuclear factor 4alpha (HNF-4alpha) and HNF-1alpha impair insulin secretion and cause maturity onset diabetes of the young (MODY). HNF-4alpha is known to be an essential positive regulator of HNF-1alpha. More recent data demonstrates that HNF-4alpha expression is dependent on HNF-1alpha in mouse pancreatic islets and exocrine cells. This effect is mediated by binding of HNF-1alpha to a tissue-specific promoter (P2) located 45.6 kb upstream from the previously characterized Hnf4alpha promoter (P1). Here we report that the expression of HNF-4alpha in human islets and exocrine cells is primarily mediated by the P2 promoter. Furthermore, we describe a G --> A mutation in a conserved nucleotide position of the HNF-1alpha binding site of the P2 promoter, which cosegregates with MODY. The mutation results in decreased affinity for HNF-1alpha, and consequently in reduced HNF-1alpha-dependent activation. These findings provide genetic evidence that HNF-1alpha serves as an upstream regulator of HNF-4alpha and interacts directly with the P2 promoter in human pancreatic cells. Furthermore, they indicate that this regulation is essential to maintain normal pancreatic function.     

Clinical application of 1,5-anhydroglucitol measurements in patients with hepatocyte nuclear factor-1alpha maturity-onset diabetes of the young

OBJECTIVE—1,5-anhydroglucitol (1,5-AG) is a short-term marker of metabolic control in diabetes. Its renal loss is stimulated in hyperglycemic conditions by glycosuria, which results in a lowered plasma concentration. As a low renal threshold for glucose has been described in hepatocyte nuclear factor-1α (HNF-1α) maturity-onset diabetes of the young (MODY), the 1,5-AG level may be altered in these patients. The purpose of this study was to assess the 1,5-AG levels in patients with HNF-1α MODY and in type 2 diabetic subjects with a similar degree of metabolic control. In addition, we aimed to evaluate this particle as a biomarker for HNF-1α MODY.RESEARCH DESIGN AND METHODS—We included 33 diabetic patients from the Polish Nationwide Registry of MODY. In addition, we examined 43 type 2 diabetic patients and 47 nondiabetic control subjects. The 1,5-AG concentration was measured with an enzymatic assay (GlycoMark). Receiver operating characteristic (ROC) curve analysis was used to evaluate 1,5-AG as a screening marker for HNF-1α MODY.RESULTS—The mean 1,5-AG plasma concentration in diabetic HNF-1α mutation carriers was 5.9 μg/ml, and it was lower than that in type 2 diabetic patients (11.0 μg/ml, P = 0.003) and in nondiabetic control subjects (23.9 μg/ml, P < 0.00005). The ROC curve analysis revealed 85.7% sensitivity and 80.0% specificity of 1,5-AG in screening for HNF-1α MODY at the criterion of <6.5 μg/ml in patients with an A1C level between 6.5 and 9.0%.CONCLUSIONS—1,5-AG may be a useful biomarker for differential diagnosis of patients with HNF-1α MODY with a specific range of A1C, although this requires further investigation. However, the clinical use of this particle in diabetic HNF-1α mutation carriers for metabolic control has substantial limitations.1,5-anhydroglucitol (1,5-AG) is a monosaccharide that shows a structural similarity to glucose. Its main source in humans is dietary ingestion, particularly meats and cereals (1). In addition, ∼10% of 1,5-AG is derived from endogenous synthesis. 1,5-AG is generally not metabolized, and in healthy subjects it achieves a stable plasma concentration that reflects a steady balance between ingestion and urinary excretion (1).1,5-AG is reabsorbed in renal tubules by an AG/fructose/mannose common transport system that is distinct from the major glucose reabsorption system (2,3). In hyperglycemic conditions, the excess of glucose is reabsorbed owing to chemical similarity not only by its own specific active transporters, but also by the AG/fructose/mannose transporter; therefore, it competes with 1,5-AG. Subsequently, 1,5-AG urinary excretion is increased during hyperglycemia, and it results in a lowered plasma concentration (4). This explains its low plasma level in patients with poorly controlled diabetes. This particle was established in clinical practice as a short-term marker of metabolic control, and recently it has been investigated as a marker of postprandial hyperglycemia (5,6). In contrast to A1C, it reflects changes in glycemic control over a period of 1–2 weeks (5).The 1,5-AG excretion rate depends on the renal threshold for glucose (7). Thus, its clinical usefulness in evaluation of some groups of patients, for example, pregnant women and subjects with end-stage renal disease, is obvious (7,8). Interestingly, the decreased renal threshold for glucose was observed in patients with hepatocyte nuclear factor-1α (HNF-1α) maturity-onset diabetes of the young (MODY), formerly classified as MODY3, and in nondiabetic mutation carriers of this gene (9,10). Diabetes that results from HNF-1α mutations is usually accompanied by extrapancreatic features. One of them is a tubulopathy that results in a low renal threshold for glucose. An animal model suggests that it is caused by decreased expression of sodium-glucose cotransporter 2, a low-affinity, high-capacity transporter in proximal renal tubules (11). Thus, hypothetically, the increased glucose load in renal tubules in these patients may cause stronger competition with 1,5-AG for reabsorption and, subsequently, increased urinary loss. Moreover, one cannot exclude the impact of HNF-1α mutations on the expression of the AG/fructose/mannose transporter. Therefore, in HNF-1α MODY, lower plasma concentrations of 1,5-AG compared with those in other types of diabetes can be expected at a similar A1C. In the scenario of a very low 1,5-AG level, this particle should also be considered as a candidate biochemical marker for this monogenic type of diabetes, which may have considerable clinical implications and enable screening for patients with HNF-1α MODY in large cohorts, potentially avoiding the expensive and laborious technique of direct gene sequencing. In this study, we compared 1,5-AG plasma concentrations in diabetic HNF-1α mutation carriers with those in patients with type 2 diabetes and in nondiabetic subjects.     

C-Peptide responses to glucose load in maturity-onset diabetes of the young (MODY)

Pancreatic beta cell responses were measured in obese and nonobese maturity-onset diabetes of the young (MODY) patients by estimating serum immunoreactive insulin (IRI) and C-peptide (CP) during oral glucose tolerance testing (OGTT). The serum CP responses were generally low in MODY patients and more pronounced in obese patients. The IRI responses were heterogenous; some patients had normal and others low responses. It was observed that in several patients there was a relatively higher IRI concentration in comparison with the CP values, as indicated by low CP and normal IRI values. This is suggestive of altered metabolic fates of insulin and CP in the MODY patients.     

The prevalence of the HNF-1alpha G319S mutation in Canadian aboriginal youth with type 2 diabetes

OBJECTIVE: To investigate the prevalence of the unique HNF-1alpha G319S mutation in a population of aboriginal youth with type 2 diabetes and to describe the relationship between clinical and historical characteristics and the presence or absence of the HNF-1alpha G319S mutation. RESEARCH DESIGN AND METHODS: Participating youth were genotyped for the G319S mutation of the HNF-1alpha gene. Clinical, laboratory, and historical data were collected via chart review (blinded to genotype results). Comparison data were derived from another study involving young nondiabetic pregnant aboriginal women. RESULTS: A total of 51 youth seen sequentially in a type 2 diabetes clinic participated in this study. Of these, 21 (41.2%) had at least one copy of the mutant allele. The allele frequency in the study population was 0.29 (95% CI 0.20-0.38), which was significantly different from the allele frequency of 0.13 in the comparison population (chi(2) = 6.78, P = 0.009). The frequency of the homozygous mutation (S319/S319) was 0.18. Mean BMI was significantly lower (P = 0.002), mean HbA(1c) was significantly higher (P = 0.02), and acanthosis nigricans was significantly less frequent (P = 0.004) in those with the mutation compared with the wild type. Mean insulin levels were lower and insulin sensitivity (assessed by homeostasis model assessment [HOMA]) was greater in the homozygote group compared with the wild-type group (P = 0.002 and P = 0.0007, respectively). A dose-dependent gradient was observed for these characteristics. CONCLUSIONS: These data support the association between the HNF-1alpha G319S mutation and early-onset type 2 diabetes in this population. Those with the mutation lacked clinical characteristics of insulin resistance (e.g., obesity and acanthosis nigricans) and had lower insulin levels, suggesting that an insulin-secretory and/or -production defect plays an important role in the development of diabetes in this group. Further investigation of the pathophysiology of the S319 homo- and heterozygote is needed because it may impact treatment and/or prevention of this disease.     

Mutations in the genes for hepatocyte nuclear factor (HNF)-1alpha, -4alpha, -1beta, and -3beta; the dimerization cofactor of HNF-1; and insulin promoter factor 1 are not common causes of early-onset type 2 diabetes in Pima Indians

OBJECTIVE: Maturity-onset diabetes of the young (MODY) is a genetically heterogeneous subtype of type 2 diabetes characterized by an early age at onset and autosomal dominant inheritance. MODY can result from heterozygous mutations in at least five genes. The purpose of this study was to determine whether alterations in known MODY genes and two MODY candidate genes contribute to the development of early-onset type 2 diabetes in Pima Indians. RESEARCH DESIGN AND METHODS: The coding regions of the known MODY genes hepatocyte nuclear factor (HNF)-1alpha, HNF-4alpha, HNF-1beta, and insulin promoter factor 1 and the coding regions of two MODY candidate genes, HNF-3beta and the dimerization cofactor of HNF-1, were sequenced in genomic DNA from Pima Indians. The primary "affected" study population consisted of 46 Pima Indians whose age at onset of type 2 diabetes was < or =20 years. DNA sequence variants identified in the affected group were then analyzed in a group of 80 "unaffected" Pima Indians who were at least 40 years old and had normal glucose tolerance. RESULTS: A total of 11 polymorphisms were detected in these genes. However, none of the polymorphisms differed in frequency among Pima Indians with an early age at onset of diabetes compared with older Pima Indians with normal glucose tolerance. CONCLUSIONS: Mutations in these known MODY or MODY candidate genes are not a common cause of early-onset diabetes in Pima Indians.     

Novel gene mutation in maturity-onset diabetes of the young: A case report

BACKGROUND Maturity-onset diabetes of the young(MODY) is the most common monogenic type of diabetes. Recently, 14 gene mutations have been found to be associated with MODY. In addition, the KLF11 gene mutation is the pathogenic gene of MODY7. To date, the clinical and functional characteristics of the novel KLF11mutation c. G31A have not yet been reported.CASE SUMMARY We report of a 30-year-old male patient with a one-year history of nonketosisprone diabetes and a 3-generation family history of ...     

Phenotypic characteristics of early-onset autosomal-dominant type 2 diabetes unlinked to known maturity-onset diabetes of the young (MODY) genes.

OBJECTIVE: To investigate whether there are forms of early-onset autosomal-dominant type 2 diabetes that are distinct from typical maturity-onset diabetes of the young (MODY) and to characterize their phenotypic characteristics. RESEARCH DESIGN AND METHODS: The study included 220 affected subjects from 29 families in which early-onset type 2 diabetes occurred in multiple generations and was not linked to known MODY genes (MODY gene-negative families). All individuals underwent an oral glucose tolerance test and other clinical measurements aimed at investigating the underlying metabolic defect and the presence of diabetic complications. For comparison, 79 affected carriers of MODY3 (hepatocyte nuclear factor [HNF]-1 alpha) mutations were similarly examined. RESULTS: Subjects from MODY gene-negative pedigrees were diagnosed with diabetes at an older age (36 +/- 17 vs. 21 +/- 10 years, P = 0.0001) and were more frequently obese (52 vs. 18%, P = 0.0001) than MODY3 individuals. MODY gene-negative patients who were insulin treated required more exogenous insulin than did MODY3 subjects (0.7 +/- 0.4 vs. 0.45 +/- 0.2 U.kg-1.day-1, P = 0.04), despite similar C-peptide levels. Among subjects not treated with insulin, MODY gene-negative subjects had significantly higher serum insulin levels, both fasting (16.5 +/- 15 vs. 6.5 +/- 5 microU/ml, P = 0.027) and 2 h after a glucose load (53 +/- 44 vs. 11 +/- 10, P = 0.002). They also had higher serum triglycerides (P = 0.02), higher cholesterol levels (P = 0.02), more hypertension (P = 0.0001), and more nephropathy (P = 0.001). Differences persisted when families were matched for age at diagnosis. CONCLUSIONS: Our findings indicate the existence of forms of early-onset autosomal-dominant type 2 diabetes that are distinct from MODY and are frequently characterized by insulin resistance, similar to later-onset type 2 diabetes. Because of the Mendelian pattern of inheritance, the goal of identifying the genes involved in these forms of diabetes appears to be particularly feasible.     

A prevalent amino acid polymorphism at codon 98 (Ala98Val) of the hepatocyte nuclear factor-1alpha is associated with maturity-onset diabetes of the young and younger age at onset of type 2 diabetes in Asian Indians

OBJECTIVE: Among Europeans, mutations in the hepatocyte nuclear factor-1alpha (HNF1alpha) gene are associated with the most common form of maturity-onset diabetes of the young (MODY)3. In Asian Indians, type 2 diabetes occurs earlier and often overlaps with MODY, but the genetics of the latter are unknown. The aim of this study was to estimate the prevalence of Ala98Val polymorphism of the HNF1alpha gene in different types of diabetes in Asian Indians. RESEARCH DESIGN AND METHODS: Genotyping of Ala98Val was done by the PCR-restriction fragment-length polymorphism method in the following groups: 1) MODY, defined as non-insulin-dependent diabetes (age at onset <25 years) and vertical transmission of diabetes through at least three generations (n = 122); 2) very-early-onset type 2 diabetes (age at onset <25 years) without family history (n = 23); 3) early-onset type 2 diabetes (age at onset between 26 and 40 years, n = 171); 4) late-onset type 2 diabetes (age at onset >40 years, n = 133); 5) type 1 diabetes (n = 150); and 6) normal glucose tolerance (n = 130). The frequency of the Val genotypes was compared in the diabetic and control groups. RESULTS: The frequency of the Val allele was significantly higher in MODY patients (P = 0.0013) compared with control groups. Furthermore, in the total group of patients with type 2-like diabetes (groups 1-4), the Val allele was associated with an earlier diagnosis of diabetes (P = 0.0002). CONCLUSIONS: Among Asian Indians, the Ala98Val polymorphism of HNF1alpha gene is associated with MODY and with earlier age at onset of type 2 diabetes.