The genetics of common variation affecting platelet development, function and pharmaceutical targeting

AD Johnson - Journal of Thrombosis and Haemostasis, 2011 - Wiley Online Library
Journal of Thrombosis and Haemostasis, 2011Wiley Online Library
Common variant effects on human platelet function and response to anti‐platelet treatment
have traditionally been studied using candidate gene approaches involving a limited
number of variants and genes. These studies have often been undertaken in clinically
defined cohorts. More recently, studies have applied genome‐wide scans in larger
population samples than prior candidate studies, in some cases scanning relatively healthy
individuals. These studies demonstrate synergy with some prior candidate gene findings …
Summary
Common variant effects on human platelet function and response to anti‐platelet treatment have traditionally been studied using candidate gene approaches involving a limited number of variants and genes. These studies have often been undertaken in clinically defined cohorts. More recently, studies have applied genome‐wide scans in larger population samples than prior candidate studies, in some cases scanning relatively healthy individuals. These studies demonstrate synergy with some prior candidate gene findings (e.g., GP6, ADRA2A) but also uncover novel loci involved in platelet function. Here, I summarise findings on common genetic variation influencing platelet development, function and therapeutics. Taken together, candidate gene and genome‐wide studies begin to account for common variation in platelet function and provide information that may ultimately be useful in pharmacogenetic applications in the clinic. More than 50 loci have been identified with consistent associations with platelet phenotypes in ≥ 2 populations. Several variants are under further study in clinical trials relating to anti‐platelet therapies. In order to have useful clinical applications, variants must have large effects on a modifiable outcome. Regardless of clinical applications, studies of common genetic influences, even of small effect, offer additional insights into platelet biology including the importance of intracellular signalling and novel receptors. Understanding of common platelet‐related genetics remains behind parallel fields (e.g., lipids, blood pressure) due to challenges in phenotype ascertainment. Further work is necessary to discover and characterise loci for platelet function, and to assess whether these loci contribute to disease aetiologies or response to therapeutics.
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