Drug-induced immune thrombocytopenia: Mapping of the drug binding site to the membrane-proximal region of platelet GPIX

Drug-induced Immune thrombocytopenia (DIT) is a common complication of several medications, including commonly used antibiotics. The most widely studied DIT is caused by quinine. In DIT, antibodies predominantly bind to the platelet membrane glycoprotein (GP) IX in a drug-dependent fashion resulting in increased platelet clearance. Binding of the sensitizing drug, such as quinine, to GPIX has been proposed but is yet to be established. This work demonstrates that quinine is retained specifically by human GPIX. Quinine binding was first analyzed in wild-type mouse platelets and in transgenic mouse platelet expressing human GPIX using high performance liquid chromatography. Binding of quinine to GPIX was then measured in Chinese hamster ovary (CHO) cells expressing a combination of wild type, human or mouse, three human/mouse chimeric constructs and six mutant GPIX proteins. Quinine was retained by human GPIX. No detectable absorption was observed with mouse GPIX or human GPIbα. The quinine binding site was mapped to residues 110–115 of human GPIX suggesting that quinine interacts with specific residues of the GP. These findings provide further insights into the molecular mechanisms of DIT.     

Rifampicin-dependent antibodies bind a similar or identical epitope to glycoprotein IX-specific quinine-dependent antibodies

The drug-dependent antibody of a patient with rifampicin-induced thrombocytopenia was characterized using the antigen-capture enzyme-linked immunosorbent assay (MAIPA assay), flow cytometry, and immunoprecipitation. The antibody was found to bind glycoprotein (GP) Ib-IX but not GPIIb-IIIa because (1) it immunoprecipitated drug-dependently the former but not the latter glycoprotein complex and (2) the MAIPA assay showed strong rifampicin-dependent antibody binding when anti-GPIb-IX monoclonal antibodies (mAbs) (AK2 and FMC25) but not anti-GPIIb-IIIa mAbs (AP2, SZ21, and SZ22) were used to capture the antigen. The antibody binding site was further localized to the GPIX subunit of the GPIb-IX complex because flow cytometric analysis revealed drug-dependent antibody binding to L cells transfected with human GPIbbeta and GPIX complementary DNA (L betaIX cells) but not with human GPIbalpha and GPIbbeta complementary DNA (L alphabeta cells). Finally, in the MAIPA assay, the rifampicin-dependent antibody almost completely cross-blocked the binding of the anti-GPIX mAb (SZ1) to platelets. Similar cross-blocking of SZ1binding to platelets by the quinine-dependent antibodies was also observed. This finding not only confirms that the epitope of the rifampicin-dependent antibody is on GPIX but it is also identical to or located in close proximity to that of the quinine-dependent antibody and SZ1. Further characterization of the epitopes of these antibodies may have important implications for a general understanding of the mechanism of drug-induced thrombocytopenia. (Blood. 2000;95:1988-1992)     

Characterization of the binding domains on platelet glycoproteins Ib-IX and IIb/IIIa complexes for the quinine/quinidine-dependent antibodies.

Sera of 12 patients with quinine/quinidine-induced thrombocytopenia showed drug-dependent antibody binding to glycoprotein (GP) Ib-IX complex. The reaction with GPIb-IX complex of 11 of these 12 sera was strongly inhibited by the complex-specific monoclonal antibodies (MoAbs) AK1 and SZ1. The exception was a quinine-induced serum designated BU. The reaction of the six quinidine-induced sera was also partially blocked by an anti-GPIX MoAb, FMC25. Only 3 of the 12 patient sera showed drug-dependent antibody binding to GPIIb/IIIa, which was strongly inhibited by the anti-GPIIIa MoAb 22C4, and the anti-GPIIb alpha MoAb SZ22. With detergent-solubilized Serratia metalloprotease-treated platelets, quinine/quinidine-induced sera, except BU, immunoprecipitated a membrane-bound proteolytic fragment of GPIb-IX complex. In contrast, BU immunoprecipitated glycocalicin and a 40-Kd peptide tail fragment of GPIb alpha from the cell supernatant. Using purified GPIb-IX complex or its components as the target antigen, all the quinine-induced sera, except BU, immunoprecipitated GPIb-IX complex but failed to immunoprecipitate GPIb, GPIX, or the complex reformed from GPIb and GPIX. The quinidine-induced sera strongly immunoprecipitated purified GPIb-IX complex, weakly immunoprecipitated purified GPIX and the recombined complex, but did not immunoprecipitate purified GPIb. The combined data suggest that one quinine-dependent antibody (BU) recognizes an epitope in the peptide tail region of GPIb alpha and the other five quinine-dependent antibodies react with a complex-specific epitope on the membrane-associated region of GPIb-IX complex, whereas each of the six quinidine-induced sera contain two drug-dependent antibodies, one reactive with the GPIb-IX complex-specific epitope and the other reactive with GPIX. The binding domain(s) on GPIIb/IIIa for the quinine/quinidine-dependent antibodies appear to be sterically close to the epitopes for 22C4 and SZ22.     

Quinine-induced thrombocytopenia: drug-dependent GPIb/IX antibodies inhibit megakaryocyte and proplatelet production in vitro

The development of immune cytopenias is a well-recognized side effect of many drugs. Quinine- and quinidine-dependent antibodies are classic examples of drug-induced effects that cause severe, life-threatening thrombocytopenia. Whereas the effects of drug-dependent antibodies on platelets have been well documented, their effects on megakaryocyte (Mk) biology are still unclear. We analyzed sera from several quinine-induced thrombocytopenia (QITP) patients on highly pure Mks (98% glycoprotein IIb-positive [GPIIb(+)]; 92% GPIX(+)) derived from human CD34(+) cells cultured with human thrombopoietin. We demonstrate by flow cytometry and confocal microscopy that QITP IgGs bind Mks efficiently in the presence of quinine. Incubation of day-4 Mks with QITP sera or purified IgG resulted in induction of apoptosis, a significant decrease in cell viability, and an increase in cell death. Furthermore, QITP sera preferentially reduced the number of late GPIX(+)/GPIbα(+) Mks and the number of receptors per cell in the surviving population. Ploidy distribution, lobularity, and average cell size of Mks remained unchanged after treatment. In addition, treated Mks showed a marked decrease in their proplatelet production capacity, suggesting that drug-dependent antibodies hinder platelet production. Therefore, QITP antibodies considerably reduce the proplatelet production capabilities of Mks despite undetectable effects on DNA content, morphology, and cell size.     

A site involving the "hybrid" and PSI homology domains of GPIIIa (beta 3-integrin subunit) is a common target for antibodies associated with quinine-induced immune thrombocytopenia

Drug-dependent antibodies (DDAbs) can cause the precipitous destruction of platelets if a patient is exposed to the drug for which the antibodies are specific. The molecular character of the epitopes recognized is poorly understood, and the mechanism by which drugs promote tight binding of these antibodies to platelet glycoproteins without linking covalently to protein or antibody is not yet known. We studied a group of quinine-dependent antibodies that react with human glycoprotein IIIa (GPIIIa; beta3-integrin subunit) but fail to recognize rat GPIIIa, despite close homology between the 2 proteins. By characterizing reactions of these antibodies with human/rat GPIIIa chimeras and selected GPIIIa mutants, we found that each of 3 quinine-dependent antibodies requires a 17-amino acid sequence in the newly recognized "hybrid" and PSI homology domains of GPIIIa for drug-dependent binding. Disulfide bonds are required to stabilize the target epitope. Monoclonal antibody AP3, which blocks the binding of these DDAbs to GPIIIa, was found to require a more limited stretch of the same peptide for its reaction with the glycoprotein. The findings suggest this region of GPIIIa may be a favored target for quinine-dependent antibodies and may provide a basis for further studies to elucidate the molecular basis of glycoprotein-drug-antibody interaction.     

Fine specificity of drug-dependent antibodies reactive with a restricted domain of platelet GPIIIA

Drug-induced immune thrombocytopenia is caused by drug-dependent antibodies (DDAbs) that bind tightly to platelet glycoproteins only when drug is present. How drugs mediate this interaction is not yet resolved. Several studies indicate that sites recognized by DDAbs tend to cluster in specific structural domains, suggesting they may recognize a limited number of distinct epitopes. To address this issue, we characterized the binding sites for 16 quinine-dependent antibodies thought on the basis of preliminary studies to be possibly specific for a single epitope on glycoprotein IIIa (GPIIIa). Fourteen of the antibodies reacted with a 29-kDa GPIIIa fragment comprising only the GPIIIa hybrid and plextrin-semaphorin-integrin homology domains. However, studies with mutant GPIIIa and the blocking monoclonal antibody AP3 showed that the 14 DDAbs recognize at least 6 and possibly more distinct, but overlapping, structures involving GPIIIa residues 50 to 66. The findings suggest that even antibodies specific for restricted domains on a target glycoprotein may each have a slightly different fine specificity; ie, "unique" epitopes recognized by DDAbs may be rare or nonexistent. The observations are consistent with a recently proposed model in which drug reacts noncovalently with both target protein and antibody to promote binding of an otherwise nonreactive immunoglobulin.     

Characterization of multiple quinine-dependent antibodies in a patient with episodic hemolytic uremic syndrome and immune agranulocytosis.

A 23-year-old woman experienced six distinct episodes of severe combined neutropenia and thrombocytopenia. At least one of the episodes was accompanied by hemodialysis-requiring acute renal failure and fragmentation hemolysis (hemolytic uremic syndrome [HUS]). In retrospect, all episodes were probably associated with the ingestion of quinine. Quinine-dependent antibodies to platelets, neutrophils, T lymphocytes, and red blood cells (RBCs) were detected in the patient's serum. By a monoclonal antibody antigen capture assay, the patient's serum contained IgG antibodies, which in the presence, but not absence, of quinine reacted with platelet glycoprotein (GP) complexes Ib/IX and IIb/IIIa, but not Ia/IIa. By immunoprecipitation assay, the serum, after addition of quinine, reacted strongly with an 85-Kd neutrophil membrane protein and weakly with 130- and 60-Kd moieties. Serum adsorbed with RBCs in the presence of quinine continued to react with platelets and neutrophils, and serum that was absorbed with platelets continued to react with neutrophils and RBCs, indicating that the antigenic targets were different on platelets, neutrophils, and RBCs. Since platelets and endothelial cells share some antigens, we tested patient serum for antibodies to human umbilical vein endothelial cells (HUVEC); no quinine-dependent antibodies to HUVEC were detected. However, her quinine-dependent antibodies not only bound to platelets and neutrophils, but also activated neutrophils. Thus, the patient's serum with quinine aggregated neutrophils, but neither agent alone caused activation. Moreover, the patient's serum with quinine (but not without) augmented the adherence of neutrophils to HUVEC. Treatment of the patient's serum with staphylococcal protein A removed the quinine neutrophil aggregation cofactor, suggesting it was due to IgG. In both neutrophil aggregation and adherence assays, decomplementation of the patient's serum markedly blunted its effect. Furthermore, the patient's serum failed to aggregate formalin-inactivated neutrophils, suggesting neutrophil activation, probably by activated complement, was necessary for aggregation and adhesivity to endothelium. We conclude that our patient's neutropenia, thrombocytopenia, lymphopenia, and anemia were due to quinine-dependent antibodies, and that these antibodies recognized epitopes that were different in the three target cell populations. We further suggest that HUS was likely secondary to the activation and adhesion of neutrophils to endothelium.     

Antibodies to platelet glycoproteins in haemophiliacs infected with HIV

Summary The techniques of Western blotting and the monoclonal antibody specific immobilization of platelet antigen (MAIPA) assay were used to detect antibodies to platelet glycoproteins in 43 samples of serum from 23 anti-HIV positive haemophiliacs (8 with severe thrombocytopenia, 6 with moderate thrombocytopenia, and 9 with a normal platelet count), six anti-HIV negative haemophiliacs and ten controls. Antibodies were present in the majority of anti-HIV positive patients' sera even before the onset of thrombocytopenia. Thrombocytopenia was associated with an increase in the incidence of antibodies to GPIIIa and GPIb, whereas the antigen most frequently recognized in patients without thrombocytopenia was GPIIb. Anti-GPIIb and/or GPIIIa reactivity was also seen in three out of the six anti-HIV negative patients. There was no correlation between the absolute platelet count and the detection of antibodies in either assay. Effective therapy for thrombocytopenia with zidovudine, interferon or splenectomy did not influence the presence of antibody. Eight of nine patients with AIDS were negative in the MAIPA assay, consistent with their depressed immune status. It is concluded that the production of antibodies to platelet membrane glycoprotein in anti-HIV positive haemophiliacs is influenced by factors other than HIV. The presence of such antibodies is independent of the platelet count and is therefore unlikely to play a causative role in HIV-related thrombocytopenia.     

Antibodies to platelet glycoproteins in haemophiliacs infected with HIV.

The techniques of Western blotting and the monoclonal antibody specific immobilization of platelet antigen (MAIPA) assay were used to detect antibodies to platelet glycoproteins in 43 samples of serum from 23 anti-HIV positive haemophiliacs (8 with severe thrombocytopenia, 6 with moderate thrombocytopenia, and 9 with a normal platelet count), six anti-HIV negative haemophiliacs and ten controls. Antibodies were present in the majority of anti-HIV positive patients' sera even before the onset of thrombocytopenia. Thrombocytopenia was associated with an increase in the incidence of antibodies to GPIIIa and GPIb, whereas the antigen most frequently recognized in patients without thrombocytopenia was GPIIb. Anti-GPIIb and/or GPIIIa reactivity was also seen in three out of the six anti-HIV negative patients. There was no correlation between the absolute platelet count and the detection of antibodies in either assay. Effective therapy for thrombocytopenia with zidovudine, interferon or splenectomy did not influence the presence of antibody. Eight of nine patients with AIDS were negative in the MAIPA assay, consistent with their depressed immune status. It is concluded that the production of antibodies to platelet membrane glycoprotein in anti-HIV positive haemophiliacs is influenced by factors other than HIV. The presence of such antibodies is independent of the platelet count and is therefore unlikely to play a causative role in HIV-related thrombocytopenia.     

Heparin-induced thrombocytopenia: mechanism of interaction of the heparin-dependent antibody with platelets

The interaction of the heparin-dependent antibody with heparin and platelets has been studied using the sera and purified IgG of four patients with heparin-induced thrombocytopenia. Both normal platelets and Bernard-Soulier syndrome (BSS) platelets which lack glycoprotein (GP) Ib. GPV and GPIX, aggregated in response to patient serum or IgG, but only in the presence of heparin. A monoclonal antibody (Mab) against platelet Fc II receptor (IV.3) strongly inhibited the heparin-dependent aggregation of both normal and BSS platelets induced by patient sera/IgG. Inhibition by the anti-GPIb Mab (AK2) was variable and occurred only with normal platelets. Anti-GPIX Mab (FMC 25) was not inhibitory with either normal or BSS platelets. Similar results were obtained using 14C-serotonin release instead of platelet aggregation as a measure of platelet activation. These findings suggest that (1) the reaction of the heparin-dependent antibody with platelets and heparin is mediated by a Fc-dependent mechanism, (2) GPIb, GPV and GPIX are not involved in this reaction, and (3) the inhibitory effect of anti-GPIb Mab on normal platelets is due to steric interference consistent with the platelet Fc receptor being in close proximity to GPIb.     

The autolysis loop of activated protein C interacts with factor Va and differentiates between the Arg506 and Arg306 cleavage sites

The anticoagulant human plasma serine protease, activated protein C (APC), inactivates blood coagulation factors Va (FVa) and VIIIa. The so-called autolysis loop of APC (residues 301-316, equivalent to chymotrypsin [CHT] residues 142-153) has been hypothesized to bind FVa. In this study, site-directed mutagenesis was used to probe the role of the charged residues in this loop in interactions between APC and FVa. Residues Arg306 (147 CHT), Glu307, Lys308, Glu309, Lys311, Arg312, and Arg314 were each individually, or in selected combinations, mutated to Ala. The purified recombinant protein C mutants were characterized using activated partial thromboplastin time (APTT) clotting assays and FVa inactivation assays. Mutants 306A, 308A, 311A, 312A, and 314A had mildly reduced anticoagulant activity. Based on FVa inactivation assays and APTT assays using purified Gln506-FVa and plasma containing Gln506-FV, it appeared that these mutants were primarily impaired for cleavage of FVa at Arg506. Studies of the quadruple APC mutant (306A, 311A, 312A, and 314A) suggested that the autolysis loop provides for up to 15-fold discrimination of the Arg506 cleavage site relative to the Arg306 cleavage site. This study shows that the loop on APC of residues 306 to 314 defines an FVa binding site and accounts for much of the difference in cleavage rates at the 2 major cleavage sites in FVa. (Blood. 2000;96:585-593)     

Quinine-induced immune thrombocytopenia associated with hemolytic uremic syndrome: a new clinical entity

Three patients are described who developed severe thrombocytopenia, microangiopathic hemolytic anemia, and acute renal failure after ingestion of quinine. In one patient, the same clinical findings recurred several months later after another exposure to quinine. Serum from one patient contained quinine-dependent IgG antibodies reactive with the platelet glycoprotein (GP) Ib/IX complex. In the second and third cases, serum contained IgG and IgM antibodies reactive with both the GP Ib/IX and IIb/IIIa complexes in the presence of quinine. Quinine appears to have induced both immune thrombocytopenia and the hemolytic uremic syndrome (HUS) in these individuals. Findings made in these cases may have implications for the pathogenesis of some forms of HUS.     

Heterogeneity of drug-dependent platelet antigens and their antibodies in quinine- and quinidine-induced thrombocytopenia: involvement of glycoproteins Ib, IIb, IIIa, and IX

The molecular nature of platelet receptors for quinine- and quinidine- dependent antiplatelet antibodies (Q.Ab and Qd.Ab) was studied by immunoblotting. One Q.Ab caused quinine-dependent IgG binding to platelet proteins with molecular weights (mol wts) of 174 Kd and 93 Kd and another to only a 93-Kd protein. A third Q.Ab caused binding to 174- , 140-, 93-, and 57-Kd proteins, while a fourth Q.Ab and a Qd.Ab caused IgG binding to 174- and 18-Kd proteins. Using platelets from patients with Glanzmann's thrombasthenia or Bernard Soulier syndrome and purified GPIIIa, these proteins were shown to be GPIb, GPIIb, GPIIIa, GPIX, and an unidentified 57-Kd protein missing in Bernard Soulier syndrome. Binding to the 93-Kd protein was independent of the PIA1 antigen. Absorption of one Q.Ab with Glanzmann's thrombasthenia platelets revealed different populations of antibodies with different specificities within the one patient. Thus Q.Ab and Qd.Ab are heterogeneous and may be directed toward different epitopes on major platelet glycoproteins.     

Human platelet glycoprotein IX: an adhesive prototype of leucine-rich glycoproteins with flank-center-flank structures.

The glycoprotein (GP) Ib-IX complex on the surface of human platelets functions as the von Willebrand factor receptor and mediates von Willebrand factor-dependent platelet adhesion to blood vessels. GPIX is a relatively small (Mr, 17,000) protein that may provide for membrane insertion and orientation of the larger component of the complex, GPIb (Mr, 165,000). Using antibody screening, we cloned a cDNA encoding GPIX from a human erythroleukemia cell cDNA library constructed in phage lambda gt11. Lacking a 5' untranslated region and start codon, the cDNA sequence includes 604 nucleotides, beginning with 495 bases at the 5' end coding for 165 amino acids, followed by a stop codon and 106 noncoding bases at the 3' end. By Northern blot analysis, the GPIX cDNA hybridizes with a single 1.0-kilobase species of platelet poly(A)+ RNA. Translation of the cDNA sequence gives a predicted protein sequence beginning with a truncated putative signal sequence of 5 amino acid followed by a sequence of 17 amino acids matching that determined directly by Edman degradation of intact GPIX. The predicted amino acid sequence of mature GPIX includes an NH2-terminal extracytoplasmic domain of 134 residues, a transmembrane domain of 20 residues, 6 intracytoplasmic residues, and 1 N-linked glycosylation site. GPIX contains a leucine-rich glycoprotein (LRG) sequence of 24 amino acids similar to conserved LRG sequences in GPIb and other proteins from humans, Drosophila, and yeast. "Flanking" sequences of approximately 22 amino acids are present at the NH2 and/or COOH sides of the "central" LRG sequence(s) in GPIX, GPIb, and the other human and Drosophila members of the LRG family. The role of the flank-LRG center-flank structure in the evolution and function of the LRG proteins remains to be defined.     

Specific antiplatelet glycoprotein autoantibodies are associated with the thrombocytopenia of primary antiphospholipid syndrome

Thrombocytopenia is a frequent complication of primary antiphospholipid syndrome (PAPL) and has been attributed to antibodies directed against platelet glycoproteins (Gp) and also to antiphospholipid antibodies. We tested patients with PAPL with and without thrombocytopenia for specific antiplatelet autoantibodies. Platelet autoantibodies were detected by means of platelet immunoassays which included MAIPA with a panel of monoclonal antibodies directed against all the platelet Gps known to be possible targets for platelet autoantibodies. A high prevalence of serum platelet antibodies was found in patients with thrombocytopenia (73%, 11/15 patients) whereas antiplatelet antibody was detected in only one of the 10 control patients ( P  < 0.01). The antibodies mainly recognized GpIIbIIIa ( n  = 7), but also CD9 ( n  = 5), GpIaIIa ( n  = 4), GpIbIX ( n  = 3) and GpIV ( n  = 3). Platelet-Gp antibodies eluted from the platelet surface had the same reactivity as those found in the original sera from three of the four patients tested, whereas no anticardiolipin activity was found in the platelet eluates, suggesting the absence of cross-reactivity between anticardiolipin and antiplatlet antibodies. The MAIPA assay was also performed with F(ab')2 fragments obtained by pepsin digestion of serum IgG from four patients. The same results were obtained with F(ab')2 fragments and the original serum, demonstrating that platelet antibodies specifically bind in vivo to platelet Gps via their F(ab')2 fragments. Our results suggest a link between specific platelet antibodies and the thrombocytopenia of PAPL.     

β2-肾上腺素能受体多态性/单倍型与支气管哮喘表型的相关性

目的 研究β2-肾上腺素能受体基因的多态性/单倍型与支气管舒张剂的反应性及血清免疫球蛋白E的负对数(lgIgE)间的关系.方法 2006年2月至2007年2月采用DNA测序法测定了201例哮喘患者(哮喘组)和276名健康对照者(健康对照组)的β2-AR基因5个位点(-47、-20、46、79、252)的基因型并确定其单倍型.统计学处理采用SPSS 11.5软件.以拟和优度的x2检验计算各位点基因型频率是否符合Hardy-Weinberg平衡.5个位点基因型的频率比较采用卡方检验,位点间的连锁不平衡采用确切概率法,不同基因型及单倍型与定量指标间的比较采用方差分析.如果方差分析有统计学意义,则用LSD方法对各组间的值进行两两比较.结果 哮喘组中Arg16Arg16基因型患者的支气管舒张剂反应性为(13±4)L,与Arg16Gly16基因型[(7±3)L]及G1y16Gly16基因型[(7±3)L]比较差异有统计学意义(F=81.55,P＜0.01);在哮喘组6种单倍型中,单倍型Arg16Gln27/Arg16Gln27的△FEV1最高[(13.4±3.5)L],与其他种单倍型[Gly16Gln27/Gly16Gln27(6.4±0.6)L、Gly16Glu27/Gly16Glu27(7.6±3.1)L、Gly16Gln27/Gly16Glu27(6.9±3.5)L、Gly16Gln27/Arg16Gln27(7.2±3.3)L及Gly16Glu27/Arg16Gln27(7.9±2.7)L]比较差异有统计学意义(F=32.55,P＜0.01);哮喘组中Gln27Gln27基因型患者的血清lgIgE为(2.51±0.33)IU/L,与Gln27Glu27基因型患者的血清lgIgE[(2.30±0.82)IU/L]比较差异有统计学意义(F=3.89,P＜0.05);哮喘组中单倍型Gly16Glu27/Arg16Gln27的血清lglgE最低[(2.13±0.15)IU/L],与其他4种单倍型[Arg16Gln27/Arg16Gln27为(2.56±0.14)IU/L、Gly16Glu27/Gly16Glu27为(2.40±0.16)IU/L、Gly16Gln27/Gly16Glu27为(2.54±1.26)IU/L、Gly16Gln27/Arg16Gln27为(2.48±0.48)IU/L]比较差异有统计学意义(F=3.56,P＜0.01).结论 依据所研究的哮喘表型,无论是β2-AR基因的多态性,还是单倍型均可能影响疾病的表现.     

新疆维吾尔族人β2肾上腺素能受体基因多态性与原发性高血压的相关性

目的探讨β₂肾上腺素能受体（β₂-AR）基因Arg16Gly和Gln27Glu多态性在新疆维吾尔族人原发性高血压（EH）发病中的作用。方法应用TaqMan技术检测了367例新疆维吾尔族EH患者及408例正常血压对照者Arg16Gly和Gln27Glu多态性。结果 Arg16Gly和Gln27Glu多态性在新疆维吾尔族群体中分布均符合Hardy-Weinberg平衡;Arg16GlyGG、AG、AA基因型频率和Gln27GluGG、CG和CC基因型频率在EH组和正常血压组间差异无统计学意义（P>0.05）。EH组和正常血压组间Arg16Gly及Gln27Glu位点的G等位基因频率分别为46.0%、42.5%和22.3%、24.5%,差异无统计学意义（P>0.05）。结论β₂-AR基因Arg16Gly和Gln27Glu多态位点可能不是新疆维吾尔族人群原发性高血压的遗传易感指标。     

Drug purpura due to surreptitious quinidine intake

Three patients had recurrent episodes of thrombocytopenia that resembled drug purpura, but the drug history in each case did not support the diagnosis. Although the patients specifically denied taking quinidine, serologic testing with this drug was done because the patients had access to it, and it is the commonest cause of drug purpura. Highly specific quinidine-dependent antiplatelet antibodies were found in the sera of all three patients. After being informed of the laboratory findings, the patients have had no recurrences of purpura. Serologic tests for quinidine- or quinine-dependent antibodies can help elucidate some obscure cases of purpura that may be self-induced.     

Gln27Glu and Arg16Gly polymorphisms of the beta2-adrenergic receptor gene are not associated with obesity in Japanese men

The beta2-adrenergic receptor (beta2AR), beta3AR, or uncoupling protein 1 (UCP1) may play a pathogenic role in obesity. In Swedish Caucasians, a polymorphism at codon 27 (Gln27Glu) of the beta2AR gene was shown to be associated with obesity, but no such association was shown for a polymorphism of codon 16 (Arg16Gly). Thus, we investigated whether these polymorphisms contribute to obesity in 210 Japanese men. The frequencies of the Gln27Glu and Arg16Gly polymorphisms were 0.05 and 0.48, respectively, and there was no association with obesity. A strong linkage disequilibrium between the Gln27Glu and Arg16Gly polymorphisms was shown, but there was no apparent additive effect on the clinical or metabolic characteristics. Our results suggest that the Gln27Glu and Arg16Gly polymorphisms of the beta2AR gene are not a major contributing factor to obesity in Japanese men.     

Laboratory testing for VITT antibodies

Vaccine-induced immune thrombotic thrombocytopenia (VITT) is a highly prothrombotic disorder that like heparin-induced thrombocytopenia (HIT) is caused by platelet-activating antibodies that recognize platelet factor 4 (PF4). However, unlike HIT—where heparin at low concentrations (0.1-0.5 U/mL) typically enhances antibody-induced platelet activation, platelet activation by VITT sera is usually inhibited by heparin. Further, conventional platelet activation assays for HIT, such as the serotonin-release assay (SRA) and heparin-induced platelet activation (HIPA) test, often yield negative or atypical results when testing VITT sera. Nevertheless, VITT (like HIT) is a “clinical-pathological” disorder whereby laboratory detectability of platelet-activating anti-PF4 antibodies is crucial for diagnosis. VITT antibodies follow 2 fundamental principles of HIT laboratory testing: (1) high probability of a positive PF4-dependent enzyme-immunoassay (EIA), and (2) high probability of a positive platelet activation assay. However, optimal detection of VITT in platelet activation assays requires the addition of PF4, for example, PF4-enhanced SRA (PF4-SRA) and PF4-enhanced HIPA (PIPA). A novel whole blood assay, called the PF4-induced flow cytometry-based platelet activation (PIFPA) assay, exhibits high sensitivity and specificity for VITT. HIT and VITT sera/plasmas differ in their reactivity in rapid HIT immunoassays (90-97% sensitivity for HIT, <25% sensitivity for VITT), consistent with distinct antigen sites on PF4 recognized by HIT and VITT antibodies.