Genetic risk factors of atherothrombosis.

Atherothrombosis is a preventable and multifaceted pathological disorder whose pathogenesis involves a large number of biological pathways such as lipid and hormonal metabolism, inflammation, and hemostasis. Although it has been known for a long time that atherosclerosis has a sizable hereditary component, research in the field of genetics of cardiovascular disease is still ongoing, with doubts often outweighing certainties. A large amount of evidence gathered so far allows to identify at least 5 potential important pathways that can be specifically targeted by genetic studies--lipoprotein metabolism, inflammation, the renin-angiotensin-aldosterone system, platelet function, blood coagulation, and fibrinolysis. Owing to a large number of published studies that have investigated the role of genetic polymorphisms in the pathogenesis of atherothrombosis and its complications, in this review, we focused on data emerging from meta­analyses. The available evidence suggests that some selected polymorphisms in low­density lipoprotein metabolism, C­reactive protein, and blood coagulation (especially factor V Leiden, prothrombin G20210A polymorphism, and plasminogen activator inhibitor type 1 4G/5G polymorphism) deserve particular attention. Of note, however, it seems implausible that one single polymorphism will add much to the current approach of risk assessment based on conventional risk factors. A paradigm shift would hence be needed in the current approach to the genetics of atherothrombosis, wherein the investigation of entire pathways rather than assessment of single mutations will likely provide more useful information for complex conditions that involve large numbers of genes and are subjected to environmental regulation of gene expression and cellular phenotype.

Platelet NOX, a novel target for anti-thrombotic treatment.

There is a growing body of evidence to suggest that reactive oxidant species (ROS) including O2-, OH- or H2O2 act as second messengers to activate platelets via 1) calcium mobilisation, 2) nitric oxide (NO) inactivation, and 3) interaction with arachidonic to give formation of isoprostanes. Among the enzymes generating ROS formation NOX2, the catalytic core of NADPH oxidase (NOX), plays a prominent role as shown by the almost absent ROS production by platelets taken from patients with hereditary deficiency of NOX2. Experimental and clinical studies provided evidence that NOX2 is implicated in platelet activation. Thus, impaired platelet activation has been detected in patients with NOX2 hereditary deficiency. Similarly, normal platelets added with NOX2 specific inhibitors disclosed impaired platelet activation along with ROS down-regulation. Accordingly, animals prone to atherosclerosis treated with apocynin, a NOX inhibitor, showed reduced platelet adhesion and atherosclerotic plaque. Furthermore, a significant association between NOX2 up-regulation and platelet activation has been detected in patients at athero-thrombotic risk, but a cause-effect relationship needs to be established. These findings may represent a rationale to plan interventional trials with NOX inhibitors to establish if blocking NOX2 or other NOX isoforms may represent a novel anti-platelet approach.

Racial differences in human platelet PAR4 reactivity reflect expression of PCTP and miR-376c.

Racial differences in the pathophysiology of atherothrombosis are poorly understood. We explored the function and transcriptome of platelets in healthy black (n = 70) and white (n = 84) subjects. Platelet aggregation and calcium mobilization induced by the PAR4 thrombin receptor were significantly greater in black subjects. Numerous differentially expressed RNAs were associated with both race and PAR4 reactivity, including PCTP (encoding phosphatidylcholine transfer protein), and platelets from black subjects expressed higher levels of PC-TP protein. PC-TP inhibition or depletion blocked PAR4- but not PAR1-mediated activation of platelets and megakaryocytic cell lines. miR-376c levels were differentially expressed by race and PAR4 reactivity and were inversely correlated with PCTP mRNA levels, PC-TP protein levels and PAR4 reactivity. miR-376c regulated the expression of PC-TP in human megakaryocytes. A disproportionately high number of microRNAs that were differentially expressed by race and PAR4 reactivity, including miR-376c, are encoded in the DLK1-DIO3 locus and were expressed at lower levels in platelets from black subjects. These results suggest that PC-TP contributes to the racial difference in PAR4-mediated platelet activation, indicate a genomic contribution to platelet function that differs by race and emphasize a need to consider the effects of race when developing anti-thrombotic drugs.

ALOX5AP genetic variants and risk of atherothrombotic stroke in the Taiwanese population.

We explored the role of variants of the arachidonate 5-lipoxygenase-activating protein (ALOX5AP) gene as factors for atherothrombotic stroke (ATS). A HapMap-based haplotype-tagging single nucleotide polymorphism (htSNP) association study was conducted in an isolated Taiwanese population. Multivariate logistic regression analyses revealed that patients with the GG/CG genotype of rs4293222 and the AA/AG genotype of rs4360791 had a 1.61-fold (odds ratio [OR]=1.61; 95% confidence interval [CI]=1.02-2.56, p=0.042) and a 1.69-fold (OR=1.69; 95% CI=1.00-2.86, p=0.047) increased risk of ATS, compared with patients with the CC/GG genotype, respectively. The most common haplotype allele, GTA, was used as a reference when analyzing the association between the haplotypes related to rs4293222, rs10507391, rs12429692 and ATS. The combined frequencies of all minor variant alleles of the three selected htSNP were associated with a 44% decreased risk of ATS (OR=0.56; 95% CI=0.37-0.84, p=0.005). This study provides preliminary evidence suggesting that genetic polymorphisms of ALOX5AP are associated with ATS.