The Role of Repin1 in Adipose Tissue

Since 1980 worldwide obesity has doubled in incidence to 52 % of people being overweight or obese. Obesity causes various comorbidities such as cardiovascular diseases, type II diabetes, dyslipidemia and several cancer types, making it one of the biggest challenges in worldwide health care systems. It is well known that obesity is highly heritable by either monogenetic causes or multifactorial interactions of different genes that superimpose on environmental factors and behavior. To answer questions in understanding mechanisms of obesity and/or associated metabolic pathways, mouse models have been a powerful tool. Several approaches in characterizing genes involved in obesity development through mouse engineering have been implemented, with the Cre/loxP system emerging as one of the most informative and widespread techniques. Using this approach, promoter-dependent temporal and tissue-specific regulated recombination can be achieved by Tamoxifen administration. To investigate effects of Tamoxifen on adipocyte biology in vivo, we characterized 12 weeks old male C57BL/6NTac mice after Tamoxifen treatment. We found that Tamoxifen treatment caused transient body composition changes, increased HbA1c, triglyceride and free fatty acid serum concentrations as well as smaller adipocytes in combination with browning of subcutaneous adipose tissue. Therefore, we suggest considering these effects when using Tamoxifen as a tool to induce conditional transgenic mouse models and to treat control mice in parallel. Another methodology used to identify genes involved in obesity related traits is QTL mapping in combination with congenic and subcongenic strains of mice or rats. One candidate gene that was previously identified on rat chromosome 4 is replication initiator 1 (Repin1 ). This gene was first described as a 60 kDa zinc finger protein involved in replication activation of the Chinese hamster dihydrofolate reductase (dhfr ) gene. Moreover, a triplet repeat (TTT) in the 3’UTR is associated with facets of the metabolic syndrome, including body weight, serum insulin, cholesterol and triglyceride levels. In vitro studies in 3T3-L1 cells revealed that Repin1 regulates adipocyte size, glucose transport and lipid metabolism. In this thesis functional analyses of Repin1 were performed using different Repin1 deficient mouse models. In the first study we generated a whole body Repin1 deficient db/db double knockout mouse (Rep1−/−x db/db) and systematically characterized the consequences of Repin1 deficiency. Our study provided evidence that loss of Repin1 in db/db mice improves insulin sensitivity and reduces chronic hyperglycemia most likely by reducing fat mass and adipose tissue inflammation. We next generated a liver-specific Repin1 knockout mouse (LRep1−/−) and could show that loss of Repin1 in liver leads to reduced body weight gain in combination with lower fat mass. Liver specific Repin1 deficient mice also show lower triglyceride content in the liver, improved insulin sensitivity and altered gene expression of genes involved in lipid and glucose metabolism. Finally, we inactivated the Repin1 gene in adipose tissue (iARep−/−) at an age of four weeks using Tamoxifen-inducible gene targeting strategies on a background of C57BL/6NTac mice. Mice lacking Repin1 in adipose tissue showed reduced body weight gain, decreased fat mass with smaller adipocytes, improved insulin sensitivity, lower LDL-, HDL- and total cholesterol serum concentrations and reduced expression of genes involved in lipid metabolism (Cd36 and Lcn2 ). In conclusion, the thesis presented here provides novel insights into Repin1 function. Moreover, the data clearly indicate that Repin1 plays a role in insulin sensitivity and lipid metabolism by regulating key genes involved in those pathways

Common variants in the CLDN2-MORC4 and PRSS1-PRSS2 loci confer susceptibility to acute pancreatitis

BACKGROUND/OBJECTIVES: Acute pancreatitis (AP) is one of the most common gastrointestinal disorders often requiring hospitalization. Frequent aetiologies are gallstones and alcohol abuse. In contrast to chronic pancreatitis (CP) few robust genetic associations have been described. Here we analysed whether common variants in the CLDN2-MORC4 and the PRSS1-PRSS2 locus that increase recurrent AP and CP risk associate with AP. METHODS: We screened 1462 AP patients and 3999 controls with melting curve analysis for SNPs rs10273639 (PRSS1-PRSS2), rs7057398 (RIPPLY), and rs12688220 (MORC4). Calculations were performed for the overall group, aetiology, and gender sub-groups. To examine genotype-phenotype relationships we performed several meta-analyses. RESULTS: Meta-analyses of all AP patients depicted significant (p-value<0.05) associations for rs10273639 (odds ratio (OR) 0.88, 95% confidence interval (CI) 0.81-0.97, p-value 0.01), rs7057398 (OR 1.27, 95% CI 1.07-1.5, p-value 0.005), and rs12688220 (OR 1.32, 95% CI 1.12-1.56, p-value 0.001). For the different aetiology groups a significant association was shown for rs10273639 (OR 0.76, 95% CI 0.63-0.92, p-value 0.005), rs7057398 (OR 1.43, 95% CI 1.07-1.92, p-value 0.02), and rs12688220 (OR 1.44, 95% CI 1.07-1.93, p-value 0.02) in the alcoholic sub-group only. CONCLUSIONS: The association of CP risk variants with different AP aetiologies, which is strongest in the alcoholic AP group, might implicate common pathomechanisms most likely between alcoholic AP and CP

Di-(2-Ethylhexyl)-Phthalate (DEHP) Causes Impaired Adipocyte Function and Alters Serum Metabolites

Di-(2-ethylhexyl)-phthalate (DEHP), an ubiquitous environmental contaminant, has been shown to cause adverse effects on glucose homeostasis and insulin sensitivity in epidemiological studies, but the underlying mechanisms are still unknown. We therefore tested the hypothesis that chronic DEHP exposure causes impaired insulin sensitivity, affects body weight, adipose tissue (AT) function and circulating metabolic parameters of obesity resistant 129S6 mice in vivo. An obesity-resistant mouse model was chosen to reduce a potential obesity bias of DEHP effects on metabolic parameters and AT function. The metabolic effects of 10-weeks exposure to DEHP were tested by insulin tolerance tests and quantitative assessment of 183 metabolites in mice. Furthermore, 3T3-L1 cells were cultured with DEHP for two days, differentiated into mature adipocytes in which the effects on insulin stimulated glucose and palmitate uptake, lipid content as well as on mRNA/protein expression of key adipocyte genes were investigated.We observed in female mice that DEHP treatment causes enhanced weight gain, fat mass, impaired insulin tolerance, changes in circulating adiponectin and adipose tissue Pparg, adiponectin and estrogen expression. Serum metabolomics indicated a general increase in phospholipid and carnitine concentrations. In vitro, DEHP treatment increases the proliferation rate and alters glucose uptake in adipocytes. Taken together, DEHP has significant effects on adipose tissue (AT) function and alters specific serum metabolites. Although, DEHP treatment led to significantly impaired insulin tolerance, it did not affect glucose tolerance, HOMA-IR, fasting glucose, insulin or triglyceride serum concentrations. This may suggest that DEHP treatment does not cause impaired glucose metabolism at the whole body level

The Role of Repin1 in Adipose Tissue

Since 1980 worldwide obesity has doubled in incidence to 52 % of people being overweight or obese. Obesity causes various comorbidities such as cardiovascular diseases, type II diabetes, dyslipidemia and several cancer types, making it one of the biggest challenges in worldwide health care systems. It is well known that obesity is highly heritable by either monogenetic causes or multifactorial interactions of different genes that superimpose on environmental factors and behavior. To answer questions in understanding mechanisms of obesity and/or associated metabolic pathways, mouse models have been a powerful tool. Several approaches in characterizing genes involved in obesity development through mouse engineering have been implemented, with the Cre/loxP system emerging as one of the most informative and widespread techniques. Using this approach, promoter-dependent temporal and tissue-specific regulated recombination can be achieved by Tamoxifen administration. To investigate effects of Tamoxifen on adipocyte biology in vivo, we characterized 12 weeks old male C57BL/6NTac mice after Tamoxifen treatment. We found that Tamoxifen treatment caused transient body composition changes, increased HbA1c, triglyceride and free fatty acid serum concentrations as well as smaller adipocytes in combination with browning of subcutaneous adipose tissue. Therefore, we suggest considering these effects when using Tamoxifen as a tool to induce conditional transgenic mouse models and to treat control mice in parallel. Another methodology used to identify genes involved in obesity related traits is QTL mapping in combination with congenic and subcongenic strains of mice or rats. One candidate gene that was previously identified on rat chromosome 4 is replication initiator 1 (Repin1 ). This gene was first described as a 60 kDa zinc finger protein involved in replication activation of the Chinese hamster dihydrofolate reductase (dhfr ) gene. Moreover, a triplet repeat (TTT) in the 3’UTR is associated with facets of the metabolic syndrome, including body weight, serum insulin, cholesterol and triglyceride levels. In vitro studies in 3T3-L1 cells revealed that Repin1 regulates adipocyte size, glucose transport and lipid metabolism. In this thesis functional analyses of Repin1 were performed using different Repin1 deficient mouse models. In the first study we generated a whole body Repin1 deficient db/db double knockout mouse (Rep1−/−x db/db) and systematically characterized the consequences of Repin1 deficiency. Our study provided evidence that loss of Repin1 in db/db mice improves insulin sensitivity and reduces chronic hyperglycemia most likely by reducing fat mass and adipose tissue inflammation. We next generated a liver-specific Repin1 knockout mouse (LRep1−/−) and could show that loss of Repin1 in liver leads to reduced body weight gain in combination with lower fat mass. Liver specific Repin1 deficient mice also show lower triglyceride content in the liver, improved insulin sensitivity and altered gene expression of genes involved in lipid and glucose metabolism. Finally, we inactivated the Repin1 gene in adipose tissue (iARep−/−) at an age of four weeks using Tamoxifen-inducible gene targeting strategies on a background of C57BL/6NTac mice. Mice lacking Repin1 in adipose tissue showed reduced body weight gain, decreased fat mass with smaller adipocytes, improved insulin sensitivity, lower LDL-, HDL- and total cholesterol serum concentrations and reduced expression of genes involved in lipid metabolism (Cd36 and Lcn2 ). In conclusion, the thesis presented here provides novel insights into Repin1 function. Moreover, the data clearly indicate that Repin1 plays a role in insulin sensitivity and lipid metabolism by regulating key genes involved in those pathways

The Role of Repin1 in Adipose Tissue

Since 1980 worldwide obesity has doubled in incidence to 52 % of people being overweight or obese. Obesity causes various comorbidities such as cardiovascular diseases, type II diabetes, dyslipidemia and several cancer types, making it one of the biggest challenges in worldwide health care systems. It is well known that obesity is highly heritable by either monogenetic causes or multifactorial interactions of different genes that superimpose on environmental factors and behavior. To answer questions in understanding mechanisms of obesity and/or associated metabolic pathways, mouse models have been a powerful tool. Several approaches in characterizing genes involved in obesity development through mouse engineering have been implemented, with the Cre/loxP system emerging as one of the most informative and widespread techniques. Using this approach, promoter-dependent temporal and tissue-specific regulated recombination can be achieved by Tamoxifen administration. To investigate effects of Tamoxifen on adipocyte biology in vivo, we characterized 12 weeks old male C57BL/6NTac mice after Tamoxifen treatment. We found that Tamoxifen treatment caused transient body composition changes, increased HbA1c, triglyceride and free fatty acid serum concentrations as well as smaller adipocytes in combination with browning of subcutaneous adipose tissue. Therefore, we suggest considering these effects when using Tamoxifen as a tool to induce conditional transgenic mouse models and to treat control mice in parallel. Another methodology used to identify genes involved in obesity related traits is QTL mapping in combination with congenic and subcongenic strains of mice or rats. One candidate gene that was previously identified on rat chromosome 4 is replication initiator 1 (Repin1 ). This gene was first described as a 60 kDa zinc finger protein involved in replication activation of the Chinese hamster dihydrofolate reductase (dhfr ) gene. Moreover, a triplet repeat (TTT) in the 3’UTR is associated with facets of the metabolic syndrome, including body weight, serum insulin, cholesterol and triglyceride levels. In vitro studies in 3T3-L1 cells revealed that Repin1 regulates adipocyte size, glucose transport and lipid metabolism. In this thesis functional analyses of Repin1 were performed using different Repin1 deficient mouse models. In the first study we generated a whole body Repin1 deficient db/db double knockout mouse (Rep1−/−x db/db) and systematically characterized the consequences of Repin1 deficiency. Our study provided evidence that loss of Repin1 in db/db mice improves insulin sensitivity and reduces chronic hyperglycemia most likely by reducing fat mass and adipose tissue inflammation. We next generated a liver-specific Repin1 knockout mouse (LRep1−/−) and could show that loss of Repin1 in liver leads to reduced body weight gain in combination with lower fat mass. Liver specific Repin1 deficient mice also show lower triglyceride content in the liver, improved insulin sensitivity and altered gene expression of genes involved in lipid and glucose metabolism. Finally, we inactivated the Repin1 gene in adipose tissue (iARep−/−) at an age of four weeks using Tamoxifen-inducible gene targeting strategies on a background of C57BL/6NTac mice. Mice lacking Repin1 in adipose tissue showed reduced body weight gain, decreased fat mass with smaller adipocytes, improved insulin sensitivity, lower LDL-, HDL- and total cholesterol serum concentrations and reduced expression of genes involved in lipid metabolism (Cd36 and Lcn2 ). In conclusion, the thesis presented here provides novel insights into Repin1 function. Moreover, the data clearly indicate that Repin1 plays a role in insulin sensitivity and lipid metabolism by regulating key genes involved in those pathways

Analysis of GPRC6A variants in different pancreatitis etiologies

The G-protein-coupled receptor Class C Group 6 Member A (GPRC6A) is activated by multiple ligands and is important for the regulation of calcium homeostasis. Extracellular calcium is capable to increase NLRP3 inflammasome activity of the innate immune system and deletion of this proinflammatory pathway mitigated pancreatitis severity in vivo. As such this pathway and the GPRC6A receptor is a reasonable candidate gene for pancreatitis. Here we investigated the prevalence of sequence variants in the GPRC6A locus in different pancreatitis aetiologies.We selected 6 tagging SNPs with the SNPinfo LD TAG SNP Selection tool and the functional relevant SNP rs6907580 for genotyping. Cohorts from Germany, further European countries and China with up to 1,124 patients and 1,999 controls were screened for single SNPs with melting curve analysis.We identified an association of rs1606365(G) with alcoholic chronic pancreatitis in a German (odds ratio (OR) 0.76, 95% confidence interval (CI) 0.65-0.89, p = 8 × 10-5) and a Chinese cohort (OR 0.78, 95% CI 0.64-0.96, p = 0.02). However, this association was not replicated in a combined cohort of European patients (OR 1.18, 95% CI 0.99-1.41, p = 0.07). Finally, no association was found with acute and non-alcoholic chronic pancreatitis.Our results support a potential role of calcium sensing receptors and inflammasome activation in alcoholic chronic pancreatitis development. As the functional consequence of the associated variant is unclear, further investigations might elucidate the relevant mechanisms

Di-(2-Ethylhexyl)-Phthalate (DEHP) Causes Impaired Adipocyte Function and Alters Serum Metabolites

Di-(2-ethylhexyl)-phthalate (DEHP), an ubiquitous environmental contaminant, has been shown to cause adverse effects on glucose homeostasis and insulin sensitivity in epidemiological studies, but the underlying mechanisms are still unknown. We therefore tested the hypothesis that chronic DEHP exposure causes impaired insulin sensitivity, affects body weight, adipose tissue (AT) function and circulating metabolic parameters of obesity resistant 129S6 mice in vivo. An obesity-resistant mouse model was chosen to reduce a potential obesity bias of DEHP effects on metabolic parameters and AT function. The metabolic effects of 10-weeks exposure to DEHP were tested by insulin tolerance tests and quantitative assessment of 183 metabolites in mice. Furthermore, 3T3-L1 cells were cultured with DEHP for two days, differentiated into mature adipocytes in which the effects on insulin stimulated glucose and palmitate uptake, lipid content as well as on mRNA/protein expression of key adipocyte genes were investigated.We observed in female mice that DEHP treatment causes enhanced weight gain, fat mass, impaired insulin tolerance, changes in circulating adiponectin and adipose tissue Pparg, adiponectin and estrogen expression. Serum metabolomics indicated a general increase in phospholipid and carnitine concentrations. In vitro, DEHP treatment increases the proliferation rate and alters glucose uptake in adipocytes. Taken together, DEHP has significant effects on adipose tissue (AT) function and alters specific serum metabolites. Although, DEHP treatment led to significantly impaired insulin tolerance, it did not affect glucose tolerance, HOMA-IR, fasting glucose, insulin or triglyceride serum concentrations. This may suggest that DEHP treatment does not cause impaired glucose metabolism at the whole body level

Di-(2-Ethylhexyl)-Phthalate (DEHP) Causes Impaired Adipocyte Function and Alters Serum Metabolites

Di-(2-ethylhexyl)-phthalate (DEHP), an ubiquitous environmental contaminant, has been shown to cause adverse effects on glucose homeostasis and insulin sensitivity in epidemiological studies, but the underlying mechanisms are still unknown. We therefore tested the hypothesis that chronic DEHP exposure causes impaired insulin sensitivity, affects body weight, adipose tissue (AT) function and circulating metabolic parameters of obesity resistant 129S6 mice in vivo. An obesity-resistant mouse model was chosen to reduce a potential obesity bias of DEHP effects on metabolic parameters and AT function. The metabolic effects of 10-weeks exposure to DEHP were tested by insulin tolerance tests and quantitative assessment of 183 metabolites in mice. Furthermore, 3T3-L1 cells were cultured with DEHP for two days, differentiated into mature adipocytes in which the effects on insulin stimulated glucose and palmitate uptake, lipid content as well as on mRNA/protein expression of key adipocyte genes were investigated.We observed in female mice that DEHP treatment causes enhanced weight gain, fat mass, impaired insulin tolerance, changes in circulating adiponectin and adipose tissue Pparg, adiponectin and estrogen expression. Serum metabolomics indicated a general increase in phospholipid and carnitine concentrations. In vitro, DEHP treatment increases the proliferation rate and alters glucose uptake in adipocytes. Taken together, DEHP has significant effects on adipose tissue (AT) function and alters specific serum metabolites. Although, DEHP treatment led to significantly impaired insulin tolerance, it did not affect glucose tolerance, HOMA-IR, fasting glucose, insulin or triglyceride serum concentrations. This may suggest that DEHP treatment does not cause impaired glucose metabolism at the whole body level

Di-(2-Ethylhexyl)-Phthalate (DEHP) Causes Impaired Adipocyte Function and Alters Serum Metabolites

Di-(2-ethylhexyl)-phthalate (DEHP), an ubiquitous environmental contaminant, has been shown to cause adverse effects on glucose homeostasis and insulin sensitivity in epidemiological studies, but the underlying mechanisms are still unknown. We therefore tested the hypothesis that chronic DEHP exposure causes impaired insulin sensitivity, affects body weight, adipose tissue (AT) function and circulating metabolic parameters of obesity resistant 129S6 mice in vivo. An obesity-resistant mouse model was chosen to reduce a potential obesity bias of DEHP effects on metabolic parameters and AT function. The metabolic effects of 10-weeks exposure to DEHP were tested by insulin tolerance tests and quantitative assessment of 183 metabolites in mice. Furthermore, 3T3-L1 cells were cultured with DEHP for two days, differentiated into mature adipocytes in which the effects on insulin stimulated glucose and palmitate uptake, lipid content as well as on mRNA/protein expression of key adipocyte genes were investigated.We observed in female mice that DEHP treatment causes enhanced weight gain, fat mass, impaired insulin tolerance, changes in circulating adiponectin and adipose tissue Pparg, adiponectin and estrogen expression. Serum metabolomics indicated a general increase in phospholipid and carnitine concentrations. In vitro, DEHP treatment increases the proliferation rate and alters glucose uptake in adipocytes. Taken together, DEHP has significant effects on adipose tissue (AT) function and alters specific serum metabolites. Although, DEHP treatment led to significantly impaired insulin tolerance, it did not affect glucose tolerance, HOMA-IR, fasting glucose, insulin or triglyceride serum concentrations. This may suggest that DEHP treatment does not cause impaired glucose metabolism at the whole body level

Phenotype of DEHP treated female 129S6 and control animals (n = 5 per group).

<p>Data obtained after 10 weeks of treatment are given as mean ± SEM.</p