Differenziell exprimierte Gene im Fettgewebe und ihre Rolle in der Pathophysiologie des humanen Metabolischen Syndroms

The human metabolic syndrome is characterized by a heterogenic complex of symptoms, including central obesity. Obesity itself is linked to major features of the metabolic syndrome such as insulin resistance, dyslipidemia or type 2 diabetes mellitus. It has been shown that obesity risk and resulting metabolic alterations are associated with adipose tissue distribution, adipocyte size and secretion of adipocytokines, which are in turn influenced by environmental factors and genetic susceptibility. It might be assumed that currently known genetic variants associated with obesity and/or BMI (body mass index) as well as fat distribution explain up to 20 % of the variability in BMI and so, studies employing novel strategies are inevitable. In addition to the role of genetic variation, mRNA levels of several genes have been shown to be differentially expressed in subcutaneous (SC) and visceral (Vis) adipose tissue and to be correlated with obesity-related traits. It is scarcely investigated whether the obesity risk variants also might account for the variability in mRNA expression. The present thesis deals with novel obesity candidate genes, characterized by a differential mRNA expression in various fat depots. The association of genetic variants in these genes with obesity as part of the metabolic syndrome, and related traits was investigated in well characterized German cohorts. The main method used for genotyping was described in detail in a comprehensive review providing explicit troubleshooting and description of modified protocols for specific experimental needs. Further, the influence of genotypes on the gene expression levels was examined. While the differential expression for FTO could be described for the first time, the variant rs8050136 was shown to be significantly associated with obesity but not with the expression. Genetic variants in FASN were shown to be significantly associated with obesity and related traits in a cohort of European ancestry for the very first time. Moreover, one polymorphism showed effects on the ratio of Vis/SC FASN mRNA expression. While CNR1 is controversially discussed in the literature, the present work showed rather moderate effects of genetic variants on obesity. BMPR2 could be described as a novel obesity candidate gene. Amongst others, one variant was associated with obesity in a case-control design and with BMPR2 mRNA expression in Vis adipose tissue. In conclusion, the present study revealed novel genetic variants promoting obesity, and therefore a metabolic risk, which might be partly explicable through an influence of these variants on the mRNA expression levels of the genes in the adipose tissue depots. These findings contribute to better understanding of the genetic background of obesity which is essential in order to translate experimental data into diagnostic, preventive and treatment strategies

Widely Used Commercial ELISA Does Not Detect Precursor of Haptoglobin2, but Recognizes Properdin as a Potential Second Member of the Zonulin Family

Background: There is increasing evidence for the role of impaired intestinal permeability in obesity and associated metabolic diseases. Zonulin is an established serum marker for intestinal permeability and identical to pre-haptoglobin2. Here, we aimed to investigate the relationship between circulating zonulin and metabolic traits related to obesity. Methods: Serum zonulin was measured by using a widely used commercial ELISA kit in 376 subjects from the metabolically well-characterized cohort of Sorbs from Germany. In addition, haptoglobin genotype was determined in DNA samples from all study subjects. Results: As zonulin concentrations did not correlate to the haptoglobin genotypes, we investigated the specificity of the zonulin ELISA assay using antibody capture experiments, mass spectrometry, and Western blot analysis. Using serum samples that gave the highest or lowest ELISA signals, we detected several proteins that are likely to be captured by the antibody in the present kit. However, none of these proteins corresponds to pre-haptoglobin2. We used increasing concentrations of recombinant pre-haptoglobin2 and complement C3 as one of the representative captured proteins and the ELISA kit did not detect either. Western blot analysis using both the polyclonal antibodies used in this kit and monoclonal antibodies rose against zonulin showed a similar protein recognition pattern but with different intensity of detection. The protein(s) measured using the ELISA kit was (were) significantly increased in patients with diabetes and obesity and correlated strongly with markers of the lipid and glucose metabolism. Combining mass spectrometry and Western blot analysis using the polyclonal antibodies used in the ELISA kit, we identified properdin as another member of the zonulin family. Conclusion: Our study suggests that the zonulin ELISA does not recognize pre-haptoglobin2, rather structural (and possibly functional) analog proteins belonging to the mannose-associated serine protease family, with properdin being the most likely possible candidate

Novel Mutations in the Asparagine Synthetase Gene (ASNS) Associated With Microcephaly

Microcephaly is a devastating condition defined by a small head and small brain compared to the age- and sex-matched population. Mutations in a number of different genes causative for microcephaly have been identified, e.g., MCPH1, WDR62, and ASPM. Recently, mutations in the gene encoding the enzyme asparagine synthetase (ASNS) were associated to microcephaly and so far 24 different mutations in ASNS causing microcephaly have been described. In a family with two affected girls, we identified novel compound heterozygous variants in ASNS (c.1165G > C, p.E389Q and c.601delA, p.M201Wfs∗28). The first mutation (E389Q) is a missense mutation resulting in the replacement of a glutamate residue evolutionary conserved from Escherichia coli to Homo sapiens by glutamine. Protein modeling based on the known crystal structure of ASNS of E. coli predicted a destabilization of the protein by E389Q. The second mutation (p.M201Wfs∗28) results in a premature stop codon after amino acid 227, thereby truncating more than half of the protein. The novel variants expand the growing list of microcephaly causing mutations in ASNS

Genetic Analyses of Heme Oxygenase 1 (HMOX1) in Different Forms of Pancreatitis

Contains fulltext : 107993.pdf (publisher's version ) (Open Access)BACKGROUND: Heme oxygenase 1 (HMOX1) is the rate limiting enzyme in heme degradation and a key regulator of inflammatory processes. In animal models the course of pancreatitis was ameliorated by up-regulation of HMOX1 expression. Additionally, carbon monoxide released during heme breakdown inhibited proliferation of pancreatic stellate cells and might thereby prevent the development of chronic pancreatitis (CP). Transcription of HMOX1 in humans is influenced by a GT-repeat located in the promoter. As such, HMOX1 variants might be of importance in the pathogenesis of pancreatitis. METHODS: The GT-repeat and SNP rs2071746 were investigated with fluorescence labelled primers and by melting curve analysis in 285 patients with acute pancreatitis, 208 patients with alcoholic CP, 207 patients with idiopathic/hereditary CP, 147 patients with alcoholic liver cirrhosis, and in 289 controls, respectively. GT-repeat analysis was extended to a total of 446 alcoholic CP patients. In addition, we performed DNA sequencing in 145 patients with alcoholic CP, 138 patients with idiopathic/hereditary CP, 147 patients with alcoholic liver cirrhosis, and 151 controls. Exon 3 screening was extended to additional patients and controls. RESULTS: S- and L-alleles of the GT-repeat, genotypes and alleles of SNP rs2071746 and non-synonymous variants detected by sequencing were found with similar frequencies in all groups. CONCLUSIONS: Although functional data implicate a potential influence of HMOX1 variants on the pathogenesis of pancreatitis, we did not find any association. As rare non-synonymous HMOX1 variants were found in patients and controls, it is rather unlikely that they will have functional consequences essential for pancreatitis development

A Common Variant of PNPLA3 (p.I148M) Is Not Associated with Alcoholic Chronic Pancreatitis

Contains fulltext : 110441.pdf (publisher's version ) (Open Access)BACKGROUND: Chronic pancreatitis (CP) is an inflammatory disease that in some patients leads to exocrine and endocrine dysfunction. In industrialized countries the most common aetiology is chronic alcohol abuse. Descriptions of associated genetic alterations in alcoholic CP are rare. However, a common PNPLA3 variant (p.I148M) is associated with the development of alcoholic liver cirrhosis (ALC). Since, alcoholic CP and ALC share the same aetiology PNPLA3 variant (p.I148M) possibly influences the development of alcoholic CP. METHODS: Using melting curve analysis we genotyped the variant in 1510 patients with pancreatitis or liver disease (961 German and Dutch alcoholic CP patients, 414 German patients with idiopathic or hereditary CP, and 135 patients with ALC). In addition, we included in total 2781 healthy controls in the study. RESULTS: The previously published overrepresentation of GG-genotype was replicated in our cohort of ALC (p-value <0.0001, OR 2.3, 95% CI 1.6-3.3). Distributions of genotype and allele frequencies of the p.I148M variant were comparable in patients with alcoholic CP, idiopathic and hereditary CP and in healthy controls. CONCLUSIONS: The absence of an association of PNPLA3 p.I148M with alcoholic CP seems not to point to a common pathway in the development of alcoholic CP and alcoholic liver cirrhosis

Genetic and Evolutionary Analyses of the Human Bone Morphogenetic Protein Receptor 2 (BMPR2) in the Pathophysiology of Obesity

Human bone morphogenetic protein receptor 2 (BMPR2) is essential for BMP signalling and may be involved in the regulation of adipogenesis. The BMPR2 locus has been suggested as target of recent selection in human populations. We hypothesized that BMPR2 might have a role in the pathophysiology of obesity.Evolutionary analyses (dN/dS, Fst, iHS) were conducted in vertebrates and human populations. BMPR2 mRNA expression was measured in 190 paired samples of visceral and subcutaneous adipose tissue. The gene was sequenced in 48 DNA samples. Nine representative single nucleotide polymorphisms (SNPs) were genotyped for subsequent association studies on quantitative traits related to obesity in 1830 German Caucasians. An independent cohort of 925 Sorbs was used for replication. Finally, relation of genotypes to mRNA in fat was examined.The evolutionary analyses indicated signatures of selection on the BMPR2 locus. BMPR2 mRNA expression was significantly increased both in visceral and subcutaneous adipose tissue of 37 overweight (BMI>25 and <30 kg/m²) and 80 obese (BMI>30 kg/m²) compared with 44 lean subjects (BMI< 25 kg/m²) (P<0.001). In a case-control study including lean and obese subjects, two intronic SNPs (rs6717924, rs13426118) were associated with obesity (adjusted P<0.05). Combined analyses including the initial cohort and the Sorbs confirmed a consistent effect for rs6717924 (combined P = 0.01) on obesity. Moreover, rs6717924 was associated with higher BMPR2 mRNA expression in visceral adipose tissue.Combined BMPR2 genotype-phenotype-mRNA expression data as well as evolutionary aspects suggest a role of BMPR2 in the pathophysiology of obesity

Differenziell exprimierte Gene im Fettgewebe und ihre Rolle in der Pathophysiologie des humanen Metabolischen Syndroms

The human metabolic syndrome is characterized by a heterogenic complex of symptoms, including central obesity. Obesity itself is linked to major features of the metabolic syndrome such as insulin resistance, dyslipidemia or type 2 diabetes mellitus. It has been shown that obesity risk and resulting metabolic alterations are associated with adipose tissue distribution, adipocyte size and secretion of adipocytokines, which are in turn influenced by environmental factors and genetic susceptibility. It might be assumed that currently known genetic variants associated with obesity and/or BMI (body mass index) as well as fat distribution explain up to 20 % of the variability in BMI and so, studies employing novel strategies are inevitable. In addition to the role of genetic variation, mRNA levels of several genes have been shown to be differentially expressed in subcutaneous (SC) and visceral (Vis) adipose tissue and to be correlated with obesity-related traits. It is scarcely investigated whether the obesity risk variants also might account for the variability in mRNA expression. The present thesis deals with novel obesity candidate genes, characterized by a differential mRNA expression in various fat depots. The association of genetic variants in these genes with obesity as part of the metabolic syndrome, and related traits was investigated in well characterized German cohorts. The main method used for genotyping was described in detail in a comprehensive review providing explicit troubleshooting and description of modified protocols for specific experimental needs. Further, the influence of genotypes on the gene expression levels was examined. While the differential expression for FTO could be described for the first time, the variant rs8050136 was shown to be significantly associated with obesity but not with the expression. Genetic variants in FASN were shown to be significantly associated with obesity and related traits in a cohort of European ancestry for the very first time. Moreover, one polymorphism showed effects on the ratio of Vis/SC FASN mRNA expression. While CNR1 is controversially discussed in the literature, the present work showed rather moderate effects of genetic variants on obesity. BMPR2 could be described as a novel obesity candidate gene. Amongst others, one variant was associated with obesity in a case-control design and with BMPR2 mRNA expression in Vis adipose tissue. In conclusion, the present study revealed novel genetic variants promoting obesity, and therefore a metabolic risk, which might be partly explicable through an influence of these variants on the mRNA expression levels of the genes in the adipose tissue depots. These findings contribute to better understanding of the genetic background of obesity which is essential in order to translate experimental data into diagnostic, preventive and treatment strategies

Differenziell exprimierte Gene im Fettgewebe und ihre Rolle in der Pathophysiologie des humanen Metabolischen Syndroms

The human metabolic syndrome is characterized by a heterogenic complex of symptoms, including central obesity. Obesity itself is linked to major features of the metabolic syndrome such as insulin resistance, dyslipidemia or type 2 diabetes mellitus. It has been shown that obesity risk and resulting metabolic alterations are associated with adipose tissue distribution, adipocyte size and secretion of adipocytokines, which are in turn influenced by environmental factors and genetic susceptibility. It might be assumed that currently known genetic variants associated with obesity and/or BMI (body mass index) as well as fat distribution explain up to 20 % of the variability in BMI and so, studies employing novel strategies are inevitable. In addition to the role of genetic variation, mRNA levels of several genes have been shown to be differentially expressed in subcutaneous (SC) and visceral (Vis) adipose tissue and to be correlated with obesity-related traits. It is scarcely investigated whether the obesity risk variants also might account for the variability in mRNA expression. The present thesis deals with novel obesity candidate genes, characterized by a differential mRNA expression in various fat depots. The association of genetic variants in these genes with obesity as part of the metabolic syndrome, and related traits was investigated in well characterized German cohorts. The main method used for genotyping was described in detail in a comprehensive review providing explicit troubleshooting and description of modified protocols for specific experimental needs. Further, the influence of genotypes on the gene expression levels was examined. While the differential expression for FTO could be described for the first time, the variant rs8050136 was shown to be significantly associated with obesity but not with the expression. Genetic variants in FASN were shown to be significantly associated with obesity and related traits in a cohort of European ancestry for the very first time. Moreover, one polymorphism showed effects on the ratio of Vis/SC FASN mRNA expression. While CNR1 is controversially discussed in the literature, the present work showed rather moderate effects of genetic variants on obesity. BMPR2 could be described as a novel obesity candidate gene. Amongst others, one variant was associated with obesity in a case-control design and with BMPR2 mRNA expression in Vis adipose tissue. In conclusion, the present study revealed novel genetic variants promoting obesity, and therefore a metabolic risk, which might be partly explicable through an influence of these variants on the mRNA expression levels of the genes in the adipose tissue depots. These findings contribute to better understanding of the genetic background of obesity which is essential in order to translate experimental data into diagnostic, preventive and treatment strategies

Role of vaspin in human eating behaviour.

OBJECTIVE: The adipokine vaspin (visceral adipose tissue derived serine protease inhibitor, serpinA12) follows a meal-related diurnal variation in humans and intracerebroventricular vaspin administration leads to acutely reduced food intake in db/db mice. We therefore hypothesized that vaspin may play a role in human eating behaviour. MATERIALS AND METHODS: We measured serum vaspin concentrations in 548 subjects from a self-contained population of Sorbs (Germany) who underwent detailed metabolic testing including eating behaviour assessments using the three-factor eating questionnaire. In addition, genetic variation within vaspin was assessed by genotyping 28 single nucleotide polymorphisms (SNPs) in all study subjects. RESULTS: Serum vaspin concentrations correlated positively with restraint, disinhibition and hunger (all P<0.05), although the correlations did not withstand further adjustments for age, gender and BMI (all P>0.05). Independent of observed correlations, genetic variants in vaspin were associated with serum vaspin levels but showed no significant association with any of the eating behaviour phenotypes after accounting for multiple testing (P≥0.05 after adjusting for age, gender and BMI). CONCLUSION: Our data suggest that serum vaspin concentrations might modulate human eating behaviour, which does not seem to be affected by common genetic variation in vaspin