Henrik Vestergaard

Aminoacid polymorphisms of insulin receptor substrate-1 in non-insulin-dependent diabetes mellitus.

Since relative or absolute insulin deficiency and insulin insensitivity are involved in the aetiology of non-insulin-dependent diabetes mellitus (NIDDM), we examined whether patients with NIDDM exhibit genetic variability in the coding region of insulin receptor substrate-1 (IRS-1), a candidate gene that is ubiquitous in insulin-sensitive and insulin-like growth factor 1 (IGF1) sensitive tissues, including those that determine glucose production and clearance and those with regulatory effects on pancreatic beta-cell function. IRS-1 has a central role as an adaptor molecule that links the insulin-receptor and IGF1-receptor kinases with enzymes that regulate cellular metabolism and growth. Single-stranded conformation polymorphism analysis and direct nucleotide sequencing were applied to genomic DNA from 86 unrelated patients with NIDDM and 76 normoglycaemic controls. 10 of the patients with NIDDM and 3 of the controls were heterozygous at codon 972 for a polymorphism in which glycine was substituted with arginine. Moreover, at codon 513, 6 patients with NIDDM and 2 controls had a heterozygous polymorphism with a transition from alanine to proline. None of the polymorphism carriers had both aminoacid variants and the total allelic frequency of IRS-1 polymorphisms was about three times higher in patients with NIDDM than in controls (p = 0.02). Both aminoacid substitutions were located close to tyrosine phosphorylation motifs that are putative recognition sites for insulin and IGF1 signal transmission proteins. Analysis of the phenotypes showed that patients with NIDDM who had IRS-1 variants did not differ in their degree of insulin resistance compared with patients without known IRS-1 polymorphisms. However, carriers of the codon 972 variant had significantly lower plasma levels of fasting insulin and C-peptide. Our results suggest that aminoacid polymorphisms in IRS-1 may be involved in the aetiology of a subset of late-onset NIDDM.

Glycogen synthase and phosphofructokinase protein and mRNA levels in skeletal muscle from insulin-resistant patients with non-insulin-dependent diabetes mellitus.

In patients with non-insulin-dependent diabetes mellitus (NIDDM) and matched control subjects we examined the interrelationships between in vivo nonoxidative glucose metabolism and glucose oxidation and the muscle activities, as well as the immunoreactive protein and mRNA levels of the rate-limiting enzymes in glycogen synthesis and glycolysis, glycogen synthase (GS) and phosphofructokinase (PFK), respectively. Analysis of biopsies of quadriceps muscle from 19 NIDDM patients and 19 control subjects showed in the basal state a 30% decrease (P < 0.005) in total GS activity and a 38% decrease (P < 0.001) in GS mRNA/microgram DNA in NIDDM patients, whereas the GS protein level was normal. The enzymatic activity and protein and mRNA levels of PFK were all normal in diabetic patients. In subgroups of NIDDM patients and control subjects an insulin-glucose clamp in combination with indirect calorimetry was performed. The rate of insulin-stimulated nonoxidative glucose metabolism was decreased by 47% (P < 0.005) in NIDDM patients, whereas the glucose oxidation rate was normal. The PFK activity, protein level, and mRNA/microgram DNA remained unchanged. The relative activation of GS by glucose-6-phosphate was 33% lower (P < 0.02), whereas GS mRNA/micrograms DNA was 37% lower (P < 0.05) in the diabetic patients after 4 h of hyperinsulinemia. Total GS immunoreactive mass remained normal. In conclusion, qualitative but not quantitative posttranslational abnormalities of the GS protein in muscle determine the reduced insulin-stimulated nonoxidative glucose metabolism in NIDDM.

Impaired activity and gene expression of hexokinase II in muscle from non-insulin-dependent diabetes mellitus patients.

After entering the muscle cell, glucose is immediately and irreversibly phosphorylated to glucose-6-phosphate by hexokinases (HK) I and II. Previous studies in rodents have shown that HKII may be the dominant HK in skeletal muscle. Reduced insulin-stimulated glucose uptake and reduced glucose-6-phosphate concentrations in muscle have been found in non-insulin-dependent diabetes mellitus (NIDDM) patients when examined during a hyperglycemic hyperinsulinemic clamp. These findings [correction of finding] are consistent with a defect in glucose transport and/or phosphorylation. In the present study comprising 29 NIDDM patients and 25 matched controls, we tested the hypothesis that HKII activity and gene expression are impaired in vastus lateralis muscle of NIDDM patients when examined in the fasting state. HKII activity in a supernatant of muscle extract accounted for 28 +/- 5% in NIDDM patients and 40 +/- 5% in controls (P = 0.08) of total muscle HK activity when measured at a glucose media of 0.11 mmol/liter and 31 +/- 4 and 47 +/- 7% (P = 0.02) when measured at 0.11 mmol/liter of glucose. HKII mRNA, HKII immunoreactive protein level, and HKII activity were significantly decreased in NIDDM patients (P < 0.0001, P = 0.03, and P = 0.02, respectively) together with significantly decreased glycogen synthase mRNA level and total glycogen synthase activity (P = 0.02 and P = 0.02, respectively). In the entire study population HKII activity estimated at 0.11 and 11.0 mM glucose was inversely correlated with fasting plasma glucose concentrations (r = -0.45, P = 0.004; r = -0.54, P < 0.0001, respectively) and fasting plasma nonesterified fatty acid concentrations (r = -0.46, P = 0.003; r = -0.37, P = 0.02, respectively). In conclusion, NIDDM patients are characterized by a reduced activity and a reduced gene expression of HKII in muscle which may be secondary to the metabolic peturbations. HKII contributes with about one-third of total HK activity in a supernatant of human vastus lateralis muscle.

Mutational analysis of the coding region of the uncoupling protein 2 gene in obese NIDDM patients: impact of a common amino acid polymorphism on juvenile and maturity onset forms of obesity and insulin resistance.

Summary Recently, a gene encoding a novel human uncoupling protein, designated UCP2, was discovered. The murine UCP2 was mapped to a region on mouse chromosome 7 which in several models has been shown to be linked to obesity and hyperinsulinaemia. Single strand conformation polymorphism (SSCP) analysis and direct sequencing of the coding region of the UCP2 gene in 35 obese Caucasian NIDDM patients of Danish ancestry revealed one nucleotide substitution, replacing an alanine with a valine at codon 55. The amino acid polymorphism was present in 24 of the 35 (69 %) examined subjects. The allelic frequency of the A/V55 variant was 48.3 % (95 % CI: 42.5–54.1 %) among 144 subjects with juvenile onset obesity, 45.6 % (40.5–50.7 %) among 182 subjects randomly selected at the draft board examination, and 45.5 % (37.1–53.9 %) among lean control subjects selected from the same study cohort. Within these cohorts there were no differences in BMI values at different ages among wild-type carriers and A/V55 carriers. In a population-based sample of 369 young healthy Caucasians the variant showed no association with alterations in BMI, waist-to-hip ratio, fat mass or weight gain during childhood or adolescence. The A/V55 polymorphism was not related to alterations in fasting values of serum insulin and C-peptide or to an impaired insulin sensitivity index. We conclude that genetic variability in the human UCP2 gene is not a common factor contributing to NIDDM in obese Danish Caucasian subjects and the common A/V55 amino acid polymorphism of the gene is not implicated in the pathogenesis of juvenile or maturity onset obesity or insulin resistance in Caucasians. [Diabetologia (1997) 40: 1227–1230]

EXPRESSION OF PROTEIN-TYROSINE PHOSPHATASES IN THE MAJOR INSULIN TARGET TISSUES

Protein‐tyrosine phosphatases (PTPs) are key regulators of the insulin receptor signal transduction pathway. We have performed a detailed analysis of PTP expression in the major human insulin target tissues or cells (liver, adipose tissue, skeletal muscle and endothelial cells). To obtain a representative picture, all tissues were analyzed by PCR using three different primer sets corresponding to conserved regions of known PTPs. A total of 24 different PTPs were identified. A multiprobe RNase protection assay was developed to obtain a semi‐quantitative measure of the expression levels of selected PTPs. Surprisingly, PTP‐LAR, previously suggested to be a major regulator of the insulin receptor tyrosine kinase, was expressed in extremely low levels in skeletal muscle, whereas the related receptor‐type PTP‐σ and PTP‐α were expressed in relatively high levels in all four tissues. The low levels of LAR PTP mRNA in skeletal muscle were further confirmed by Northern blot analysis.

Sequence of the Human Glycogen-Associated Regulatory Subunit of type 1 Protein Phosphatase and Analysis of Its Coding Region and mRNA Level in Muscle From Patients With NIDDM

Impaired insulin-stimulated glycogen synthesis of peripheral tissues is a characteristic feature of many patients with non-insulin-dependent diabetes mellitus (NIDDM) and their first-degree relatives with normal glucose tolerance, suggesting putative inherited defects in this metabolic pathway. In previous studies, we have failed to reveal mutations in the coding regions of the muscle-specific glycogen synthase gene and the three genes that encode the catalytic subunits of protein phosphatase 1 (PP1) as frequent causes of insulin resistance. Because the glycogen-associated regulatory subunit of protein phosphatase 1 (PP1 G-subunit) plays a key role in the insulin stimulation of glycogen synthesis and the activity of PP1 is decreased in insulin-resistant subjects, we have now cloned the human G-subunit cDNA to search for abnormalities in the corresponding gene (designated PPP1R3 in the human genome nomenclature) in patients with NIDDM. The human cDNA was isolated from a skeletal muscle cDNA library and was found to encode a 126-kDa protein, which shows 73% amino acid identity to the rabbit PP1 G-subunit. The human G-subunit cDNA from 30 insulin-resistant NIDDM patients was analyzed for genetic variations in the G-subunit by using single-stranded conformation polymorphism (SSCP) scanning of reversely transcribed mRNA. One variant SSCP profile was detected in the region encoding the COOH-terminal part of the PP1 G-subunit in only one NIDDM patient, and subsequent nucleotide sequencing showed a C to A transversion on one allele at base position 2792. This change predicts an amino acid substitution from alanine to glutamic acid. The carrier of this mutation was characterized by reduced insulin-stimulated nonoxidative glucose metabolism when examined with the euglycemic hyperinsulinemic clamp. SSCP scanning of the 2584–2844 nucleotide fragment of PP1 G-subunit cDNA from an additional 22 NIDDM patients and 29 control subjects did not reveal additional genetic variants. To indirectly screen for abnormalities in PP1 G-subunit gene regulation, we measured the mRNA level of the G-subunit in skeletal muscle. However, no difference in the abundance of mRNA of PP1 G-subunit was found between patients with diabetes and control subjects.

Genetic Variants in Promoters and Coding Regions of the Muscle Glycogen Synthase and the Insulin-Responsive GLUT4 Genes in NIDDM

To examine the hypothesis that variants in the regulatory or coding regions of the glycogen synthase (GS) and insulin-responsive glucose transporter (GLUT4) genes contribute to insulin-resistant glucose processing of muscle from non-insulin-dependent diabetes mellitus (NIDDM) patients, promoter regions and regions of importance for translation, as well as coding sequences of the two genes, were studied using single-strand conformation polymorphism (SSCP) analysis and DNA sequencing. The genetic analyses were performed in subgroups of 52 Caucasian NIDDM patients and 25 age-matched healthy volunteers. By applying inverse polymerase chain reaction and direct DNA sequencing, 532 base pairs (bp) of the GS promoter were identified and the transcriptional start site determined by primer extension. SSCP scanning of the promoter region detected five single nucleotide substitutions, positioned at 42, –16, –43, –143, and –250. The three most common variants could be excluded for having major impact on allele-specific GS mRNA expression in muscle. Scanning of GS cDNA revealed one frequent silent polymorphism at codon 342. Moreover, SSCP analysis of ∼900 bp of the promoter, the 5′-untranslated region, and the coding region of the GLUT4 gene showed four polymorphisms, all single nucleotide substitutions, positioned at –581, 1, 30, and 582. None of the three changes in the regulatory region of the gene had any major influence on expression of the GLUT4 gene in muscle. The variant at 582 in the GLUT4 cDNA was a silent polymorphism at codon 130. Southern blotting of both gene loci did not detect any major abnormalities. These findings, altogether, suggest that genetic abnormalities in the GS and GLUT4 genes are unlikely to be major contributors to the insulin-resistant glucose utilization in muscle among Caucasian NIDDM patients.

Chromosomal mapping and mutational analysis of the coding region of the glycogen synthase kinase-3α and β isoforms in patients with NIDDM

Summary Activation of glycogen synthesis in skeletal muscle in response to insulin results from the combined inactivation of glycogen synthase kinase-3 (GSK-3) and activation of the protein phosphatase-1, changing the ratio between the inactive phosphorylated state of the glycogen synthase to the active dephosphorylated state. In a search for genetic defects responsible for the decreased insulin stimulated glycogen synthesis seen in patients with non-insulin-dependent diabetes mellitus (NIDDM) and their glucose-tolerant first-degree relatives we have performed mutational analysis of the coding region of the 2 isoforms of GSK-3α and GSK-3β in 72 NIDDM patients and 12 control subjects. No structural changes were detected apart from a few silent mutations. Mapping of the GSK-3α to chromosome 19q13.1–13.2 and the GSK-3β to chromosome 3q13.3-q21 outside known genetic loci linked to NIDDM further makes it unlikely that these genes are involved in the pathogenesis of common forms of NIDDM. [Diabetologia (1997) 40: 940–946]

Studies of insulin resistance in congenital generalized lipodystrophy

Two well‐characterized patients with congenital, generalized lipodystrophy have been studied by the euglycaemic hyperinsulinaemic clamp technique in combination with indirect calorimetry. Furthermore, glycogen synthase in muscle biopsies was studied in one patient with regard to enzyme activity, immunoreactive protein and mRN A levels. The patients had fasting hyperinsulinaemia, and the rate of total glucose disposal was severely impaired, primarily due to a decreased non‐oxidative glucose metabolism. In the patient studied with muscle biopsy, the expected activation of glycogen synthase by insulin did not occur. In both patients there was severely increased hepatic glucose output in the basal state, suggesting a failure of insulin to suppress hepatic gluconeogenesis. During insulin infusion a substantially elevated rate of lipid oxidation remained in the patients, in contrast to the almost completely suppressed lipid oxidation in the controls. It is concluded that patients with congenital generalized lipodystrophy may present severe insulin resistance with regard to hepatic glucose production as well as muscle glycogen synthesis and lipid oxidation. The results suggest a postreceptor defect in the action of insulin in congenital generalized lipodystrophy. The further localization of such a defect is hampered by the still incomplete understanding of the pathways that link insulin‐stimulated tyrosine phosphorylation to the ultimate action of insulin upon target cells.

Impaired Insulin-Stimulated Nonoxidative Glucose Metabolism in Pancreas-Kidney Transplant Recipients: Dose-Response Effects of Insulin on Glucose Turnover

Insulin resistance is a characteristic feature in recipients of a pancreas transplant, but the relative contribution of the liver and peripheral tissues to this abnormality within a spanning range of insulin concentrations is unknown. To assess the impact of insulin action on glucose metabolism after pancreas transplantation, a euglycemic-hyperinsulinemic clamp with sequential insulin infusions (5, 40, and 200 mU m−2·min−1 for 120 min each), combined with isotopic determinations of the rates of hepatic glucose production and extrahepatic glucose uptake, indirect calorimetry, and measurements of glycogen synthase and hexokinase activities in vastus lateralis muscle, were performed in six pancreas-kidney transplant recipients (Px group) and compared with those performed in six nondiabetic kidney transplant recipients with similar immunosuppression (Kx group) and six nondiabetic control subjects. The overall effects of insulin on whole-body glucose metabolism, determined as the glucose infusion rates versus the corresponding steady-state serum insulin concentrations, demonstrated a rightward shift in the dose-response curves of the transplanted groups compared with those of normal subjects. The dose-response curve for glucose disposal rates (Rd) was shifted to the right in the Px and Kx groups, and the maximal glucose disposal rate was reduced by 40% in the Px group (11.7 ±1.1 mg·kg−1 fat-free mass·min−1) and 30% in the Kx group (13.9 ± 1.2 mg·kg−1 fat-free mass·min−1) compared with that in control subjects (19.1 ±2.2 mg·kg−1 fat-free mass·min−1) (P < 0.05). The dose-response curve for suppression of hepatic glucose output rates was similar at increasing hepatic sinusoidal insulin concentrations.Glucose oxidation rates were similar in all groups, whereas nonoxidative glucose rates were reduced by 50% in the Px group and by 30% in the Kx group compared with those in the control group (P < 0.05). In the Px group, an impaired activation of the fractional velocity and absent decrease in the half-maximal stimulation of muscle glycogen synthase occurred during the insulin infusion. However, this finding could only explain in part the degree of impairment in nonoxidative glucose metabolism. No differences were found in total hexokinase activity in muscle between normal subjects and the transplant groups at basal insulinemia or after insulin stimulation. During hyperinsulinemia, glucagon and nonesterified fatty acids were not suppressed as much in the transplanted groups as they were in normal control subjects (P < 0.05). In conclusion, pancreas transplantation causes impaired peripheral action of insulin as compared with that in normal subjects and kidney transplant recipients. The main course of insulin resistance in the two transplant groups is explained by the immunosuppressive treatment, but the augmented insulin resistance in pancreas transplant recipients could partly be explained by the chronic peripheral hyperinsulinemia. The principal site of insulin resistance was a reduced insulin-stimulated nonoxidative glucose metabolism of peripheral tissues, which resulted in decreased capacity to store glucose as glycogen. The impaired peripheral insulin action could only partly be explained by a reduced activation of the glycogen synthase enzyme in skeletal muscle.