Mutations of the apolipoprotein A5 gene with inherited hypertriglyceridaemia: review of the current literature.

Apoliporotein A5 (APOA5), a member of the apolipoprotein family, plays a key regulatory role in triglyceride (TG) metabolism. Even though the exact biochemical background of its mechanism is not yet fully understood, diseases associated with this particular gene highlighted its key role in the metabolism of triglycerides in humans. Naturally occurring functional variants of the gene and their natural major haplotypes are known to associate with moderately elevated triglyceride levels, and are also known to confer risk or protection for major polygenic diseases, like coronary heart disease, stroke, or metabolic syndrome. On the other hand, case reports and even robust resequencing studies verified APOA5 mutations as underlying genetic defects behind extreme hypertriglyceridemic phenotype. Soon after the recognition of the first cases, there were indications which suggest the existence of less frequent genetic variants which, in combination with the common allelic variants of the gene, can define haplotypes that are associated with substantial triglyceride level increase. In addition, it became evident, that there are rare mutations of the APOA5 gene which can be associated with specific complex phenotypes and different types of hyperlipoproteinemia, which includes extremely high triglyceride levels with multiple organ pathology. These rare mutations may cause inheritable hypertriglyceridemia, but they presented at a low frequency and could not be captured by standard genotyping array screenings. The identification of new mutations still relies on the direct sequencing of APOA5 gene of patients with hypertriglyceridemia with an unusual pattern, individually or in huge resequencing studies.

Investigation of JAK2, STAT3 and CCR6 polymorphisms and their gene-gene interactions in inflammatory bowel disease.

Genome-wide association studies identified many loci associated with the two forms of inflammatory bowel disease (IBD), Crohn's disease (CD) and ulcerative colitis (UC). Components of the interleukin-23 signalling pathway, such as IL23R, JAK2 and STAT3, have been implicated in both diseases. In addition, emerging evidence supports the role of IL23-driven Th17 cells in inflammation. Here, we studied the susceptibility nature of three components of IL23 signalling and Th17 cell differentiation: JAK2 rs10758669, STAT3 rs744166 and CCR6 rs2301436 initially associated with CD in Hungarian CD and UC patients. A total of 616 unrelated subjects with either form of IBD and 496 healthy controls were genotyped with PCR-RFLP methods. We also tested the genetic interactions of JAK2, STAT3 and CCR6 polymorphisms in a pairwise fashion with regard to disease risk. We could confirm the susceptibility of STAT3 rs744166 TT homozygotes for UC (OR: 1.483, 95% CI: 1.103-1.992, P = 0.009). Data on genetic interaction reveals that the above JAK2 and STAT3 risk alleles contribute to CD susceptibility in combination with each other (OR: 2.218; 95% CI: 1.097-4.487; P = 0.024), while the JAK2 variant shows a tendency to confer UC risk only on a wild-type STAT3 background (OR: 1.997, 95%CI: 0.994-4.009, P = 0.049). Our results may help in understanding how these natural variants contribute to development of IBD through their genetic association.

Triglyceride level affecting shared susceptibility genes in metabolic syndrome and coronary artery disease.

Metabolic syndrome is characterized primarily by abdominal obesity, high triglyceride- and low HDL cholesterol levels, elevated blood pressure, and increased fasting glucose levels, which are often associated with coronary heart diseases. Several factors, such as physical inactivity, age, and several endocrine and genetic factors can increase the risk of the development of the disease. Gathered evidence shows, that metabolic syndrome is not only a risk factor for cardiovascular disease, but often both of them have the same shared susceptibility genes, as several genetic variants have shown a predisposition to both diseases. Due to the spread of robust genome wide association studies, the number of candidate genes in metabolic syndrome and coronary heart disease susceptibility increases very rapidly. From the growing spectrum of the genes influencing lipid metabolism (like the LPL; PPARA; APOE; APOAI/CIII/AIV genecluster and APOAS5), the current review focuses on shared susceptibility variants involved in triglyceride metabolism and consequently the effects on the circulating triglyceride levels. As the elevated levels of triglycerides can be associated with disease phenotypes, some of these SNPs can have susceptibility features in both metabolic syndrome and in coronary heart disease, thereby some of them can even represent a kind of susceptibility link between metabolic syndrome and coronary artery disease.