Shirley A. Williams

Lack of association between aspirin responsiveness and seven candidate gene haplotypes in patients with symptomatic vascular disease

We studied the effect of prophylactic aspirin (ASA) ingestion on platelet function in 463 patients with stroke, transient ischemic attack (TIA) or acute coronary disease (ACD), using the Platelet Function Analyzer-100 (PFA-100). We correlated ASA responsiveness with haplotypes of seven candidate genes, selected for their documented role in platelet function, namely, the genes for integrins alpha2beta1and alphaIIbbeta3 (ITGA2, ITGA2B, and ITGB3), platelet glycoproteins Ibalpha and VI (GPIBA and GP6), the purinergic receptor P2Y1 (P2RY1), and prostaglandin H synthase 1 (PTGS1 = COX1). Non-responsiveness to ASA was defined as the failure of prior ASA ingestion to prolong the PFA-100 closure time (CT) when blood was perfused through cartridges coated with collagen plus epinephrine (CEPI-CT). ASA non-responsiveness was observed in 114 of 463 patients (24.6 %), but was not associated with haplotypes of any of the seven candidate genes. There was also no association between any haplotypes and the CT when blood was perfused through cartridges coated with collagen plus ADP (CADP-CT). The ASA non-responsive cohort had significantly increased whole blood platelet counts (p = 0.03) and plasma von Willebrand Factor antigen levels (p < 0.001), which likely contributes to resistance to the inhibitory effects of ASA in the PFA-100.

Genetics of platelet reactivity in normal, healthy individuals

Summary.  Background: The Platelet Function Analyzer‐100 (PFA‐100) is widely used to measure platelet reactivity in whole blood under high shear. Objective: To characterize the genetic component of platelet reactivity among normal individuals, using the PFA‐100. Methods: We compared baseline platelet reactivity with sex, age, platelet count, hematocrit, plasma von Willebrand factor antigen (VWF:Ag), and alleles of seven candidate genes: integrin subunits α2 (ITGA2) and β3 (ITGB3), platelet glycoproteins GPIbα (GP1BA) and GPVI (GP6), purinogenic receptors (P2RY1 and P2RY12) and cyclooxygenase‐1 (COX1). Results: Based on linear and logistic regression models, we report an inverse correlation between baseline closure time (CT) initiated by collagen plus epinephrine (CEPI) and plasma VWF:Ag level, ITGA2 807T and P2RY1 893C, and an inverse correlation between baseline CT initiated by collagen plus adenosine diphosphate (CADP) and P2RY1 893C or GP1BA ‐5C. Conclusions: These results indicate that genetic polymorphisms in ITGA2 and P2RY1 combine with plasma VWF:Ag levels to modulate baseline platelet reactivity in response to collagen plus EPI, while genetic differences in P2RY1 and GP1BA significantly effect platelet responses to collagen plus ADP. Our results demonstrate that the PFA‐100 can be used to evaluate the effects of genetic predictors of platelet function.

Genetic variants that affect platelet function.

Purpose of reviewThis review summarizes our current knowledge of common gene variants (polymorphisms) that have small individual effects on platelet function in humans, but can cumulatively lead to hyperreactive platelets and increase risk for negative outcomes in thrombotic disorders. Recent findingsCandidate gene association and genome-wide association studies (GWAS) have identified loci that include single nucleotide polymorphisms, which exert a cumulative effect on platelet function by modifying basic platelet parameters, such as mean platelet volume (MPV) or platelet count, by altering the expression or activity of key platelet receptors, or by influencing downstream effector pathways utilized by these receptors. SummaryVariation in MPV between normal individuals is responsible for roughly a two-fold range in platelet protein content, including key surface receptors and reactive granule constituents, the association of ADRA2, GP1BA, GP6, ITGA2 and P2Y12 variants with platelet reactivity, initially identified by candidate gene analyses, has now been validated by genome-wide approaches in much larger individual cohorts, and GWAS have identified novel gene variants, most notably PEAR1, that participate in variation in platelet reactivity among normal individuals, all of which contribute to a genetic basis for differences in platelet reactivty among normal individuals.

The low-frequency isoform of platelet glycoprotein VIb attenuates ligand-mediated signal transduction but not receptor expression or ligand binding

The 2 most common haplotypes of human GP6, GP6a and GP6b, generate the allelic isoforms glycoprotein VI (GPVI)a and GPVIb that differ by 5 amino acids: S219P, K237E, and T249A in the ectodomains, and Q317L and H322N in the cytoplasmic domain. By quantitative Western blot, we found no association between GP6 genotype and total platelet GPVI content among 132 normal subjects. When expressed as soluble products or as membrane-associated receptors, GPVIa and GPVIb have identical affinities for type I collagen, collagen-related peptide, or convulxin. However, the cytoplasmic domain substitutions in GPVIb have a significant effect on GPVI-dependent subcellular associations and ligand-induced signal transduction. L317 increases binding to calmodulin, whereas N322 attenuates binding to Fyn/Lyn. Consistent with the latter finding, convulxin-induced Syk phosphorylation is significantly attenuated in Dami cells stably transfected with GPVIb, relative to GPVIa. This represents direct evidence that haplotype-related GPVI functional differences are inherent in the cytoplasmic domain substitutions, whereby GPVIb binds less strongly to Fyn/Lyn and attenuates the rate and extent of Syk phosphorylation. These allelic differences in GP6a and GP6b explain functional differences in the respective isoforms, but the molecular basis for the several-fold range in GPVI levels of human platelets remains to be determined.

Mean Platelet Volume and Integrin Alleles Correlate With Levels of Integrins αIIbβ3 and α2β1 in Acute Coronary Syndrome Patients and Normal Subjects

Objective— The interindividual variation in platelet &agr;2&bgr;1 exceeds a 2-fold variance in platelet &agr;IIb&bgr;3 level. Our objective was to parse the contribution of mean platelet volume (MPV) and integrin gene alleles to this variation in large cohorts of patients with acute coronary syndrome (ACS) and normal subjects. Methods and Results— Platelet &agr;IIb&bgr;3 and &agr;2&bgr;1 levels were measured by flow cytometry in whole blood from 320 ACS patients and 128 normal subjects and compared with MPV, platelet count, ITGA2 rs1126643, and ITGB3 rs5918 alleles. In all subjects, a strong direct correlation was found between MPV and &agr;IIb&bgr;3 level (P<0.001). Neither MPV nor &agr;IIb&bgr;3 level correlated with ITGB3 rs5918 alleles. In the case of &agr;2&bgr;1 level, MPV contributed modestly, whereas ITGA2 rs1126643 exerted a greater effect. An inverse correlation was found between MPV and the rs1126643 minor allele. Conclusion— MPV is the major effector of platelet &agr;IIb&bgr;3 level, whereas the ITGA2 rs1126643 alleles influence &agr;2&bgr;1 level more than MPV does. The rs1126643 minor allele, associated with lower MPV, likely exerts this effect via the influence of &agr;2&bgr;1 on megakaryocyte maturation. Because of the hyperactivity of larger platelets, MPV is an accurate metric of risk for adverse outcome in ACS.

Enhanced binding of poly(ADP-ribose)polymerase-1 and Ku80/70 to the ITGA2 promoter via an extended cytosine-adenosine repeat.

Background We have identified a cytosine-adenosine (CA) repeat length polymorphism in the 5′-regulatory region of the human integrin α2 gene ITGA2 that begins at −605. Our objective was to establish the contribution of this polymorphism to the regulation of integrin α2β1 expression, which is known to vary several-fold among normal individuals, and to investigate the underlying mechanism(s). Methodology/Principal Findings In combination with the SNP C-52T, previously identified by us as a binding site for the transcription factor Sp1, four ITGA2 haplotypes can be distinguished, in the order in which they enhance ITGA2 transcription: (CA)12/-52C>(CA)11/-52C>(CA)11/-52T>(CA)10/-52T. By DNA affinity chromatography and chromatin immunoprecipitation (ChIP) assays, we show that poly (ADP-ribose)polymerase-1 (PARP-1) and Ku80/70 bind specifically and with enhanced affinity to the longer (CA)12 repeat alleles. Conclusions/Significance The increased binding of PARP-1 and Ku80/70, known components of transcription co-activator complexes, to the longer (CA)12 alleles of ITGA2 coincides with enhanced α2β1 expression. The most likely explanation for these findings is that PARP-1 and Ku80/70 contribute to the transcriptional regulation of ITGA2. These observations provide new insight into the mechanisms(s) underlying haplotype-dependent variability in integrin α2β1 expression in human platelets and other cells.

Tissue Factor Inflammatory Response Regulated by Promoter Genotype and p38 MAPK in Neonatal vs. Adult Microvascular Endothelial Cells

Objective and designVariable tissue factor (TF) expression by human microvascular endothelial cells (HMVEC) may be regulated by two promoter haplotypes, distinguished by an 18-basepair deletion (D) or insertion (I) at −1,208. We sought to determine the relationship between these haplotypes and interleukin-1α (IL-1α)-induced TF expression in neonatal versus adult HMVEC.ResultsIL-1-stimulated TF mRNA, protein, and activity were significantly higher in neonatal compared to adult D/D donors. IL-1-stimulated HMVEC from neonatal D/D donors expressed threefold higher levels of TF mRNA, twofold higher TF protein, and fourfold increased TF activity compared to HMVEC from adult D/D donors. These results indicate that homozygosity for the D haplotype is characterized by increased response to IL-1 in neonates, but not adults. IL-1 induced increased phosphorylation of p38 mitogen-activated protein kinase (MAPK), which was significantly greater in neonatal compared to adult HMVEC. Moreover, inhibition of the p38 MAPK pathway reduced IL-1-stimulated TF mRNA expression in D/D neonatal but not adult HMVEC.ConclusionsUpregulation of D/D neonatal HMVEC TF expression by IL-1 is mediated through the p38 MAPK pathway. This heightened response of D/D neonatal HMVEC to inflammatory stimuli may contribute to increased microvascular coagulopathies in susceptible newborn infants.

Platelet adhesion to decorin but not collagen I correlates with the integrin α2 dimorphism E534K, the basis of the human platelet alloantigen (HPA)-5 system

A single nucleotide polymorphism in the integrin α2 gene ITGA2 (rs1801106; G1600A) creates the non-conservative amino acid substitution E534K, the basis of the human platelet alloantigen system HPA-5. Yet HPA-5 alleles do not influence binding of α2β1 to its primary ligand collagen I, and the effect of HPA-5 on platelet function has not been determined. We used a direct platelet adhesion assay to evaluate whether differential inheritance of HPA-5 alleles influences platelet adhesion to collagen I or an alternative ligand, decorin. Platelets from donors bearing one or more minor allele HPA-5b showed attenuated adhesion to purified decorin but not collagen I. Adhesion to decorin was significantly inhibited by human alloantibodies specific for HPA-5a but not by the collagen I sequence GFOGER or α2-specific inhibitory monoclonal antibodies. The minor allele 534K attenuates platelet adhesion to decorin but not collagen I, providing the first evidence of a functional effect of HPA-5 alleles.

Allele-specific wild-type TP53 expression in the unaffected carrier parent of children with Li–Fraumeni syndrome

Li-Fraumeni syndrome (LFS) is an autosomal dominant disorder where an oncogenic TP53 germline mutation is passed from parent to child. Tumor protein p53 is a key tumor suppressor regulating cell cycle arrest in response to DNA damage. Paradoxically, some mutant TP53 carriers remain unaffected, while their children develop cancer within the first few years of life. To address this paradox, response to UV stress was compared in dermal fibroblasts (dFb) from an affected LFS patient vs. their unaffected carrier parent. UV induction of CDKN1A/p21, a regulatory target of p53, in LFS patient dFb was significantly reduced compared to the unaffected parent. UV exposure also induced significantly greater p53[Ser15]-phosphorylation in LFS patient dFb, a reported property of some mutant p53 variants. Taken together, these results suggested that unaffected parental dFb may express an increased proportion of wild-type vs. mutant p53. Indeed, a significantly increased ratio of wild-type to mutant TP53 allele-specific expression in the unaffected parent dFb was confirmed by RT-PCR-RFLP and RNA-seq analysis. Hence, allele-specific expression of wild-type TP53 may allow an unaffected parent to mount a response to genotoxic stress more characteristic of homozygous wild-type TP53 individuals than their affected offspring, providing protection from the oncogenesis associated with LFS.