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Apolipoprotein E4 association with metabolic syndrome depends on body fatness.
Torres-Perez, E, Ledesma, M, Garcia-Sobreviela, MP, Leon-Latre, M, Arbones-Mainar, JM
Atherosclerosis. 2016;:35-42
Abstract
BACKGROUND AND AIMS The human Apolipoprotein E (APOE) gene is polymorphic. The APOE*4 allele is a risk factor for cardiovascular disease and could contribute to the development of the metabolic syndrome (MetS) as it may affect all MetS components. We hypothesize that the common APOE4 polymorphism differentially regulates MetS risk and that this association might be modulated by body fatness. METHODS & RESULTS We used body mass index (BMI) as surrogate of fatness and cross-sectionally studied the prevalence of MetS in 4408 middle-aged men of the Aragon Workers Health Study (AWHS). Our analysis revealed i) a gene dose-dependent association between APOE*4 allele and increased risk for MetS, ii) this association primarily derived from the overweight subjects. For these individuals, the MetS risk was higher in APOE*4 carriers than in non-carriers (Odds Ratio = 1.31; 95% CI, 1.03-1.67). Additionally, we examined 3908 healthy young individuals from the Coronary Artery Risk Development in Young Adults (CARDIA) cohort, followed-up for 25 years. Compared with APOE*4 non-carriers, APOE*4 presence significantly increased the risk of developing MetS (Hazard Ratio, 1.12; 95% CI, 1.00-1.26). Again, an interplay between APOE*4 and the longitudinal development of fatness towards the onset of MetS occurred throughout the study. For individuals with BMI gain below the median, the cumulative onset rate of MetS was significantly higher in APOE*4 carriers than in the non-carriers (HR, 1.29; 95% CI, 1.07-1.55). CONCLUSIONS Carrying APOE*4 alleles increases MetS in a dose-dependent manner, characterizing individual's APOE genotype might help identify at-risk subjects for preventive intervention.
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The DRD3 Ser9Gly Polymorphism Predicted Metabolic Change in Drug-Naive Patients With Bipolar II Disorder.
Chang, TT, Chen, SL, Chang, YH, Chen, PS, Chu, CH, Chen, SH, Huang, SY, Tzeng, NS, Wang, LJ, Wang, TY, et al
Medicine. 2016;(24):e3488
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Abstract
Patients with bipolar II disorder (BDII) have a higher prevalence rate of metabolic disturbance. Whether BDII itself, in addition to its current standard treatment, is a risk factor for metabolic syndrome warrants additional study. The dopamine receptor D3 (DRD3) gene, one of the candidate genes for BDII, is also involved in the dopaminergic system. We investigated whether it is related to changes in the metabolic indices of patients with BDII given 12 weeks of standard treatment.Patients with a first diagnosis of BDII (n = 117) were recruited. Metabolic profiles (cholesterol, triglycerides, fasting serum glucose, body mass index) were measured at baseline and at 2, 8, and 12 weeks. The genotype of the DRD3 Ser9Gly polymorphism (rs6280) was determined. Multiple linear regressions with generalized estimating equation methods were used.Seventy-six (65.0%) patients completed the 12-week intervention. Significant differences in triglyceride change were associated with the DRD3 Ser9Gly genotype (P = 0.03). Patients with the Ser/Ser genotype had significantly smaller triglyceride increases and a lower risk of developing metabolic syndrome than did those with the Ser/Gly+Gly/Gly genotype. However, the associations between the DRD3 Ser9Gly polymorphism with changes in triglyceride level become nonsignificant after correcting for multiple comparisons.We conclude that the DRD3 Ser9Gly polymorphism is nominally associated with changes in triglycerides and metabolic syndrome after 12 weeks of standard BDII treatment.
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The fat-mass and obesity-associated (FTO) gene, physical activity, and risk of incident cardiovascular events in white women.
Ahmad, T, Chasman, DI, Mora, S, Paré, G, Cook, NR, Buring, JE, Ridker, PM, Lee, IM
American heart journal. 2010;(6):1163-9
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Abstract
BACKGROUND Variation in the Fat-Mass and Obesity-Associated (FTO) gene has been associated with obesity, diabetes, and hypertension. However, its association with cardiovascular disease (CVD) in healthy populations and any interaction with physical activity remain unclear. METHODS The FTO rs8050136 allele was determined in a prospective cohort study of 21,674 apparently healthy White US women in the Women's Genome Health Study. RESULTS During a mean follow-up of 12.7±2.0 years, 664 incident CVD events occurred. The risk allele (A) was associated with higher prevalence of hypertension, diabetes, and metabolic syndrome (all P<.05). In a multivariate model, there was significant association of the risk allele with CVD (hazard ratio [HR] per allele copy 1.14, 95% CI 1.01-1.28) that was no longer significant after additional adjustment for body mass index (BMI) (HR 1.10, 95% CI 0.97-1.23). There was statistical evidence of an interaction between FTO and physical activity (P=.048). We found a significant association of FTO with CVD only among less-active (≤8.8 metabolic equivalent-h/wk) women (HR 1.19, 95% CI 1.02-1.38) in multivariate analyses that included BMI. More-active women did not have this increased risk (HR 0.96, 95% CI 0.79-1.16]). In a model that adjusted for BMI, less-active/high-risk (A/A) women were at 54% increased risk of developing CVD (HR 1.54, 95% CI 1.13-2.11), compared to more-active/low-risk (C/C) women. CONCLUSIONS Carriers of the FTO risk allele have an increased risk of CVD mediated by BMI. There appears to be an interaction with physical activity, such that this risk increase is only in less-active women.
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Inherited conduction system abnormalities--one group of diseases, many genes.
Wolf, CM, Berul, CI
Journal of cardiovascular electrophysiology. 2006;(4):446-55
Abstract
The cardiac conduction system can be anatomically, developmentally, and molecularly distinguished from the working myocardium. Abnormalities in cardiac conduction can occur due to a variety of factors, including developmental and congenital defects, acquired injury or ischemia of portions of the conduction system, or less commonly due to inherited diseases that alter cardiac conduction system function. So called "idiopathic" conduction system degeneration may have familial clustering, and therefore is consistent with a hereditary basis. This "Molecular Perspectives" will highlight several diverse mechanisms of isolated conduction system disease as well as conduction system degeneration associated with other cardiac and non-cardiac disorders. The first part of this review focuses on channelopathies associated with conduction system disease. Human genetic studies have identified mutations in the sodium channel SCN5A gene causing tachyarrhythmia disorders, as well as progressive cardiac conduction system diseases, or overlapping syndromes. Next, the importance of embryonic developmental genes such as homeobox and T-box transcription factors are highlighted in conduction system development and function. Conduction system diseases associated with multisystem disorders, such as muscular and myotonic dystrophies, will be described. Last, a new glycogen storage cardiomyopathy associated with ventricular preexcitation and progressive conduction system degeneration will be reviewed. There are a myriad of mutations identified in genes encoding cardiac transcription factors, ion channels, gap junctions, energy metabolism regulators, lamins and other structural proteins. Understanding of the molecular and ionic mechanisms underlying cardiac conduction is essential for the appreciation of the pathogenesis of conduction abnormalities in structurally normal and altered hearts.
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Genetic effects of methylation diets.
Van den Veyver, IB
Annual review of nutrition. 2002;:255-82
Abstract
DNA methylation at cytosines in CpG dinucleotides can lead to changes in gene expression and function without altering the primary sequence of the DNA. Methylation can be affected by dietary levels of methyl-donor components, such as folic acid. This may be an important mechanism for environmentally induced changes in gene expression. Recent literature supports a role for DNA-methylation changes in a number of adult-onset disorders and during development. These changes may be significant for better understanding certain birth defects (e.g., neural tube defects) and the long-term consequences of early environmental influences on gene expression (metabolic programming). Optimal "methylation diets" should be investigated as part of the prevention and treatment of all these conditions, as well as in disorders such as Rett syndrome, whose primary defects may lie in DNA methylation-dependent gene regulation.