Potential role of the ABCG2-Q141K polymorphism in type 2 diabetes.

Type 2 diabetes mellitus (T2DM) is a complex metabolic disease and variations in multispecific membrane transporter functions may affect T2DM development, complications or treatment. In this work we have analyzed the potential effects of a major polymorphism, the Q141K variant of the ABCG2 transporter in T2DM. The ABCG2 protein is a multispecific xeno- and endobiotic transporter, affecting drug metabolism and playing a key role in uric acid extrusion. The ABCG2-Q141K variant, with reduced expression level and function, is present in 15-35% of individuals, depending on the genetic background of the population, and has been shown to significantly affect gout development. Several other diseases, including hypertension, chronic renal failure, and T2DM have also been reported to be associated with high serum uric acid levels, suggesting that ABCG2 may also play a role in these conditions. In this work we have compared relatively small cohorts (n = 203) of T2DM patients (n = 99) and healthy (n = 104) individuals regarding the major laboratory indicators of T2DM and determined the presence of the SNP rs2231142 (C421A), resulting the ABCG2-Q141K protein variant. We found significantly higher blood glucose and HbA1c levels in the T2DM patients carrying the ABCG2-Q141K variant. These findings may emphasize the potential metabolic role of ABCG2 in T2DM and indicate that further research should explore how prevention and treatment of this disease may be affected by the frequent polymorphism of ABCG2.

Altered gene expressions in periferal blood cells of first-degree non-diabetic relatives of type 2 diabetic patients. / [Génexpressziós eltérések keringo fehérvérsejtekben a 2-es típusú cukorbetegek elsofokú, anyagcseréjüket illetoen egészséges rokonaiban].

Introduction and aim: We were looking for altered gene expression on peripheral blood cells significant to type 2 diabetes causing the world epidemic. Method: Muscle biopsy samples of healthy volunteers with (n = 6) or without (n = 6) first degree type 2 diabetic relatives were analyzed by mRNS microarray. After confirmation of microarrays results by quantitative real-time PCR, the expression of eight differently expressed genes were further investigated on peripheral blood cells of 58 healthy volunteers without diabetic relatives and 58 healthy ones with first-degree type 2 diabetic relatives. Results: The expressions of SERPINF1 gene were significantly lover in blood cells both from females (relative quantification: FC - female: = 0.69, p<6*10-3) and males (FC - male: = 0.65, p<2*10-3) with diabetic relatives. This change may not be the consequence of worsening metabolic state as it was identical in cells of type 2 diabetic patients and in healthy volunteers with diabetic relatives. We suggest that the altered SERPINF1 gene expression in peripheral mononuclear blood cells could be a genetic definiteness. Conclusion: With the help of SERPINF1 gene expression in white blood cells and lipid and biochemical blood parameters we suggest a mathematical formula for the augury of type 2 diabetes that should be checked on a larger population, but we hope it could be used as a diabetic marker. The expression of LAMP2 gene did not differ between the two healthy groups, but it showed a maternal parent of origin effect. In the case of maternal inheritance, we found higher LAMP2 expression suggesting that gene from the mother has a determining effect. Orv Hetil. 2020; 161(18): 738-746.

Excess maternal transmission of variants in the THADA gene to offspring with type 2 diabetes.

AIMS/HYPOTHESIS: Genome-wide association studies (GWAS) have identified more than 65 genetic loci associated with risk of type 2 diabetes. However, the contribution of distorted parental transmission of alleles to risk of type 2 diabetes has been mostly unexplored. Our goal was therefore to search for parent-of-origin effects (POE) among type 2 diabetes loci in families. METHODS: Families from the Botnia study (n = 4,211, 1,083 families) were genotyped for 72 single-nucleotide polymorphisms (SNPs) associated with type 2 diabetes and assessed for POE on type 2 diabetes. The family-based Hungarian Transdanubian Biobank (HTB) (n = 1,463, >135 families) was used to replicate SNPs showing POE. Association of type 2 diabetes loci within families was also tested. RESULTS: Three loci showed nominal POE, including the previously reported variants in KCNQ1, for type 2 diabetes in families from Botnia (rs2237895: p POE = 0.037), which can be considered positive controls. The strongest POE was seen for rs7578597 SNP in the THADA gene, showing excess transmission of the maternal risk allele T to diabetic offspring (Botnia: p POE = 0.01; HTB p POE = 0.045). These data are consistent with previous evidence of allelic imbalance for expression in islets, suggesting that the THADA gene can be imprinted in a POE-specific fashion. Five CpG sites, including those flanking rs7578597, showed differential methylation between diabetic and non-diabetic donor islets. CONCLUSIONS/INTERPRETATION: Taken together, the data emphasise the need for genetic studies to consider from which parent an offspring has inherited a susceptibility allele.

[Metabolic differences in healthy first-degree female relatives of type 2 diabetic patients]. / Anyagcsere-eltérések a 2-es típusú cukorbetegek egészséges, elsofokú norokonaiban.

INTRODUCTION: Today the prevalence of type 2 diabetes reached an epidemic level. It is known that type 2 diabetes could only be prevented before the manifestation, during the "prediabetic" state, urging the development of diagnostic tests to recognize the group at risk in time. AIM: The authors explored metabolic differences between healthy, normal glucose tolerant, normal insulin resistant females having first degree relatives with and without type 2 diabetes. METHOD: Healthy, normal insulin sensitive females without (n = 26) and with (n = 18) type 2 diabetic relatives were investigated. RESULTS: Healthy females with first degree diabetic relatives had lower low density lipoproteins and higher high density lipoproteins as well as higher glucose and insulin levels at the 120 min of oral glucose test as compared to those without first degree diabetic relatives. CONCLUSIONS: These results suggest that the appearance of insulin resistance is preceded by hepatic insulin resistance and impaired lipid metabolism in the symptom-free prediabetic period of genetically susceptible females.

[Metabolic alteration in healthy men with first degree type 2 diabetic relatives]. / Anyagcsere-eltérések a 2-es típusú cukorbetegek egészséges, elso fokú férfi rokonaiban.

INTRODUCTION: The recognition of prediabetic patients with the genetic risk of type 2 diabetes is very important as prediabetes is the last stage when manifestation of diabetes could be prevented by life style modification or drug intervention. This suggests the need for diagnostic processes to trace the risk of patients in time. AIMS: The authors looked for metabolic differences between age and BMI in adjusted healthy men with or without first degree type 2 diabetic relatives. METHODS: The study included 73 healthy men (21 with and 52 without) first-degree relatives with type 2 diabetes. RESULTS: Total body and muscle tissue glucose utilization, glucose tolerance did not differ between the two groups, but free fatty acid levels were not suppressed by glucose load in subjects with diabetic relatives. In addition the body fat content, leptin and IL-6 levels were higher, while adiponectin and the free fatty acid/adiponectin ratio were significantly lover in healthy men with diabetic relatives. In this group HDL cholesterol, and the large buoyant LDL fraction were lower whereas the high density LDL - small molecular lipid fraction was higher than those measured in subjects without diabetic relatives. CONCLUSIONS: These data suggest that deteriorations of insulin sensitivity and glucose tolerance is preceded by disturbances of fatty acid metabolism. The observed alteration in free fatty acid/adiponectin ratio, and/or the absence of free fatty acid suppression during glucose tolerance tests could be a screening tool for diabetes risk among men.

[The role of osteocalcin in the connection of bone and glucose metabolism in humans]. / Az osteocalcin helye a humán cukor- és csontanyagcsere kapcsolatában.

UNLABELLED: The lack of osteoblast derived osteocalcin in mice causes reduced pancreatic beta-cell proliferation, decreased expression of insulin gene and adiponectin gene in adipocytes as well. METHODS: The relationship between insulin sensitivity, osteocalcin and bone state in 45 healthy (20 females, 25 males) and 92 glucose intolerant (51 females, 41 males) subjects was examined. Body composition, bone density, markers of bone resorption and formation as well as glucose uptake (M value for insulin sensitivity) measured by hyperinsulinemic normoglycemic clamp were determined separately in males and females. RESULTS: Osteocalcin levels were similar in the two genders, however, glucose intolerant men had lower osteocalcin levels than healthy men (24.5+/-11 vs. 18.1+/-9 ng/ml, p < 0.05). In the healthy group, we found positive correlation between osteocalcin and muscle M values (females: r = +0.319, p < 0.05, males: r = 0.481, p < 0.01), although this relationship disappeared in the glucose intolerant groups. Osteocalcin did not show correlation with adiponectin level in any of the genders. Based on a multivariate regression analysis, in all females significant independent predictors of osteocalcin level were fasting blood glucose, whole and lean body mass glucose uptake, metabolic clearance rate, estradiol and LDL-cholesterol levels (determined 92% of its value), while in all men these were serum calcium, OGTT glucose area under the curve, free fatty acid levels, insulogenic index, HOMA-R and waist/hip ratio (determined 95% of its value). The BMU index characterizing bone resorption/formation correlated significantly with the M values only in women. CONCLUSION: This study confirmed the relationship between insulin sensitivity and osteocalcin in healthy human population, although basic difference was found between the two genders which was not related to osteocalcin.

[Effect of progressive insulin resistance on the correlation of glucose metabolism and bone status]. / A progrediáló inzulinrezisztencia hatása a glükózanyagcsere csontállapot kapcsolatokra.

A paradox is hidden in the increasing number of patients with insulin resistance, Type 2 diabetes and osteoporosis, as the world wide diabetes epidemic is driven by the same obesity which protects the bones in the obese females. Our aim was to investigate the connection between the early glucose intolerance, insulin resistance and bone density and metabolism. After metabolic status of matched 20 healthy and 51 glucose intolerant women (age: 49 +/- 9 y.) was determined, hyperinsulinemic-euglycemic clamps were done, while adipo- and cytokine levels were measured. Bone mineral density over lumbar spine and the femur neck were measured by DEXA. No differences in bone density were observed between groups at any sites measured. Tight correlations were found between total body glucose utilization and bone density in healthy group (lumbar spine r = -0.4921, p < 0.05, femur neck: r = -0.4972, p < 0.05), while with deterioration of glucose metabolism this correlation disappeared (lumbar spine: r = -0.022, ns; femur neck: r = -0.3136, ns). The adiponectin was the only adipokine which correlated with lumbar spine density in both groups ( r = -0.5081, p < 0.05; -0.2804, p < 0.05), but not with femur density, where this connection disappeared with glucose intolerance ( r = -0.6742, p < 0.01; -0.1723, ns). Relations of bone metabolic markers indicated that bone resorption decreases with worsening of insulin resistance. In conclusion inverse correlations were found between bone density and glucose metabolism, or insulin sensitivity in healthy women in perimenopause, but this connection disappeared with the deterioration of glucose metabolism and progression of insulin resistance measured by the "gold standard" insulin-glucose clamps. Decreasing insulin sensitivity of bones and escape from "metabolic control" may result in frequently observed hyperdensity in Type 2 diabetics.

Simple PCR heteroduplex, SSCP mutation screening methods for the detection of novel catalase mutations in Hungarian patients with type 2 diabetes mellitus.

BACKGROUND: The enzyme catalase is the main regulator of hydrogen peroxide metabolism. Deficiency of catalase may cause high concentrations of hydrogen peroxide and increase the risk of the development of pathologies for which oxidative stress is a contributing factor, for example, type 2 diabetes mellitus. Catalase deficiency has been reported to be associated with increased frequency of diabetes mellitus in a cohort of patients in Hungary. In this cohort, the majority of mutations in the catalase gene occur in exon 2. METHODS: Type 2 diabetic patients (n=308) were evaluated for mutations in intron 1 (81 bp), exon 2 (172 bp) and intron 2 (13 bp) of the catalase gene. Screening for mutations utilized PCR single-strand conformational polymorphism (SSCP) and PCR heteroduplex methods. Verification of detected mutations was by nucleotide sequence analysis. RESULTS: A total of 11 catalase gene mutations were detected in the 308 subjects (3.57%, p<0.001). Five of the 11 were at two previously reported mutation sites: exon 2 (79) G insertion and (138) GA insertion. Six of the 11 were at five previously unreported catalase mutation sites: intron 1 (60) G-->T; intron 2 (7) G-->A and (5) G-->C; exon 2 (96) T-->A; and exon 2 (135) T-->A. The novel missense mutations on exon 2 (96 and 135) are associated with 59% and 48% decreased catalase activity, respectively; the novel G-->C mutation on intron 2 (5) is associated with a 62% decrease in catalase activity. Mutations detected on intron 1 (60) and intron 2 (7) showed no change in catalase activity. The G-->C mutation on intron 2 (5) might be a splicing mutation. The two missense mutations on exon 2 (96) and (135) cause substitutions of amino acids 53 (Asp-->Glu) and 66 (Glu-->Cys) of the catalase protein. These are close to amino acids that are important for the binding of heme to catalase, 44 (Val) and 72-75 (Arg, Val, Val, His). Changes in heme binding may be responsible for the activity losses. CONCLUSION: Mutations that cause decreased catalase activity may contribute to susceptibility to inherited type 2 diabetes mellitus. Exon 2 and neighboring introns of the catalase gene may be minor hot spots for type 2 diabetes mellitus susceptibility mutations.