Role of monogenic diabetes genes on beta cell function in Italian patients with newly diagnosed type 2 diabetes. The Verona Newly Diagnosed Type 2 Diabetes Study (VNDS) 13.

We tested the hypothesis that common genetic variability of beta-cell genes responsible for monogenic diabetes may affect beta cell function in type 2 diabetes mellitus (T2DM). We studied 794 drug- naïve GAD-negative patients with newly diagnosed T2DM (age: median=59 years; I.Q. range: 52-66; body mass index: 29.3 kg/m2; 26.6-32.9). Beta-cell function was assessed by state-of-art mathematical modeling of glucose/C-peptide curves during a 240'-300' frequently sampled oral glucose tolerance test, to provide the beta-cell responses to the rate of increase in glucose concentration (derivative control: DC) and to glucose concentration (proportional control: PC). Forty-two single nucleotide polymorphism (SNPs), selected to cover over 90% of common genetic variability, were genotyped in nine monogenic diabetes genes: HNF4A, GCK, HNF1A, PDX1, HNF1B, NEUROD1, KLF11, KCNJ11 and ABCC8. Allelic variants of four SNPs (rs1303722 and rs882019 of GCK, rs7310409 of HNF1A and rs5219 of KCNJ11) were significantly associated with DC of beta-cell secretion (all P < 0.036). Allelic variants of four other SNPs (rs2868094 and rs6031544 of HNF4A, and rs1801262 and rs12053195 of NEUROD1) were associated with PC of beta-cell secretion (P < 0.02). In multivariate models, GCK, HNF1A and KCNJ11 SNPs explained 2.5% of the DC variability of beta-cell secretion, whereas HNF4A and NEUROD1 SNPs explained 3.6% of the PC variability of beta-cell secretion. We conclude that common variability of monogenic diabetes genes is significantly associated with an impaired beta-cell function in patients with newly diagnosed T2DM; thereby, these genes might be targeted by specific treatments in T2DM.

Haplotypes of the genes (GCK and G6PC2) underlying the glucose/glucose-6-phosphate cycle are associated with pancreatic beta cell glucose sensitivity in patients with newly diagnosed type 2 diabetes from the VNDS study (VNDS 11).

BACKGROUND: Elevated fasting plasma glucose has been associated with increased risk for development of type 2 diabetes (T2D). The balance between glucokinase (GCK) and glucose-6-phosphate catalytic subunit 2 (G6PC2) activity are involved in glucose homeostasis through glycolytic flux, and subsequent insulin secretion. AIM: In this study, we evaluated the association between the genetic variability of G6PC2 and GCK genes and T2D-related quantitative traits. METHODS: In 794 drug-naïve, GADA-negative, newly diagnosed T2D patients (VNDS; NTC01526720) we performed: genotyping of 6 independent tag-SNPs within GCK gene and 5 tag-SNPs within G6PC2 gene; euglycaemic insulin clamp to assess insulin sensitivity; OGTT to estimate beta-cell function (derivative and proportional control; DC, PC) by mathematical modeling. Genetic association analysis has been conducted using Plink software. RESULTS: Two SNPs within GCK gene (rs882019 and rs1303722) were associated to DC in opposite way (both p < 0.004). Two G6PC2 variants (rs13387347 and rs560887) were associated to both parameters of insulin secretion (DC and PC) and to fasting C-peptide levels (all p < 0.038). Moreover, subjects carrying the A allele of rs560887 showed higher values of 2h-plasma glucose (2hPG) (p = 0.033). Haplotype analysis revealed that GCK (AACAAA) haplotype was associated to decreased fasting C-peptide levels, whereas, the most frequent haplotype of G6PC2 (GGAAG) was associated with higher fasting C-peptide levels (p = 0.001), higher PC (ß = 6.87, p = 0.022) and the lower 2hPG (p = 0.012). CONCLUSION: Our findings confirmed the role of GCK and G6PC2 in regulating the pulsatility in insulin secretion thereby influencing insulin-signaling and leading to a gradual modulation in glucose levels in Italian patients with newly diagnosed T2D.

PPARG2 Pro12Ala and ADAMTS9 rs4607103 as "insulin resistance loci" and "insulin secretion loci" in Italian individuals. The GENFIEV study and the Verona Newly Diagnosed Type 2 Diabetes Study (VNDS) 4.

We investigated cross-sectionally whether the type 2 diabetes (T2DM) risk alleles of rs1801282 (PPARG2) and rs4607103 (ADAMTS9) were associated with T2DM and/or insulin sensitivity (IS) and beta cell function (ßF) in Italians without and with newly diagnosed T2DM. In 676 nondiabetic subjects (336 NGR and 340 IGR) from the GENFIEV study and in 597 patients from the Verona Newly Diagnosed Type 2 Diabetes Study (VNDS), we (1) genotyped rs1801282 and rs4607103, (2) assessed ßF by C-peptide/glucose modeling after OGTT, and (3) assessed IS by HOMA-IR in both studies and by euglycemic insulin clamp in VNDS only. Logistic, linear, and two-stage least squares regression analyses were used to test (a) genetic associations with T2DM and with pathophysiological phenotypes, (b) causal relationships of the latter ones with T2DM by a Mendelian randomization design. Both SNPs were associated with T2DM. The rs4607103 risk allele was associated to impaired ßF (p < 0.01) in the GENFIEV study and in both cohorts combined. The rs1801282 genotype was associated with IS both in the GENFIEV study (p < 0.03) and in the VNDS (p < 0.03), whereas rs4607103 did so in the VNDS only (p = 0.01). In a Mendelian randomization design, both HOMA-IR (instrumental variables: rs1801282, rs4607103) and ßF (instrumental variable: rs4607103) were related to T2DM (p < 0.03-0.01 and p < 0.03, respectively). PPARG2 and ADAMTS9 variants are both associated with T2DM and with insulin resistance, whereas only ADAMTS9 may be related to ßF. Thus, at least in Italians, they may be considered bona fide "insulin resistance genes".