Cyclic thrombocytopenia related to erythropoietin-dependent anti-platelet anti-GPIV/IIIb antibody in hemodialysis.

We describe herein the case of a 65-year-old patient on chronic hemodialysis with a medical history of idiopathic thrombocytopenia who experienced numerous episodes of severe thrombocytopenia with no specific diagnosis. Further analysis of the evolution of the platelet count showed that cyclic thrombocytopenia occurred after each injection of recombinant erythropoietin (rHu-EPO). Exploration of the involved mechanisms revealed the presence of a rHu-EPO-dependent anti-GPIV/IIIb antibody associated with a significant increase in GPIV/IIIb expression on her platelets after the addition of rHu-EPO. EPO was discontinued and the patient was treated with roxadustat with favorable results on her hemoglobin and platelet counts.

New molecular basis associated with CD36-negative phenotype in the sub-Saharan African population.

BACKGROUND: CD36 glycoprotein is expressed by various cell types, including platelets (PLTs), monocytes, and erythroid precursors, and is also the receptor for several ligands. However, absence of CD36 expression seems asymptomatic and is poorly described in Caucasians. In contrast, the frequency reaches 7% and 11% in African Caribbean and Asian persons, respectively. Lack of CD36 expression exposes to the risk of immunization in case of pregnancy or PLT transfusion. Two types of deficiency have been described: in Type I, PLTs and monocytes lack CD36 expression and the subjects are homozygous or compound heterozygous for CD36 mutations, whereas in Type II, only PLTs (Type IIa), and rarely also erythroid cells (Type IIb), are affected. Molecular events leading to Type II deficiency are poorly understood. CASE REPORT: An African girl, diagnosed with homozygous sickle cell disease and regularly transfused, was assessed for PLT CD36 expression by immunofluorescence microscopy. The deficiency was then confirmed by monoclonal antibody immobilization of PLT antigen (MAIPA) assay, and the subtype was assessed by flow cytometry. The underlying molecular basis was characterized by DNA sequencing. Furthermore, we tested the serum for possible anti-CD36 immunization. RESULTS AND CONCLUSION: Flow cytometric analysis on the patient's blood samples allowed the diagnosis of Type I CD36 deficiency. CD36 antibodies, probably due to her past history of red blood cell transfusions, were identified by MAIPA and by Luminex technology assay. Interestingly, we identified through sequencing a new molecular basis involved in CD36 deficiency: two adenines were replaced by one guanine in Exon 4 (c.367_368delAAinsG) leading to a stop codon at Position 76.

Safe fetal platelet genotyping: new developments.

BACKGROUND: Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is due to maternal alloimmunization against fetal platelet (PLT) antigens. Antenatal management strategies have been developed to avoid complications such as intracranial hemorrhage. The aim of this study was to set up two reliable, noninvasive fetal genotyping assays to determine the fetal risk in pregnancies in which the father is heterozygous for the offending antigen. This study focused on human PLT antigen (HPA)-1, the most frequently implicated antigen in FNAIT in Caucasians. STUDY DESIGN AND METHODS: Two assays based on cell-free fetal DNA extracted from maternal blood samples and on real-time polymerase chain reaction (QPCR) were developed: an allele-specific QPCR specifically targeting the polymorphic sequence in HPA-1 and the study of the variation in the high-resolution melting curve of amplicons containing the polymorphic region. RESULTS: All results from the 49 samples obtained from 29 pregnant women were consistent with expectations. Six women were compatible with their fetuses (three HPA-1aa women and three HPA-1bb women), 41 HPA-1bb women were incompatible with their fetuses, as were two HPA-1aa women. CONCLUSION: Two fetal PLT genotyping assays on maternal blood samples proved to be reliable as of 15 weeks of gestation, thereby avoiding invasive techniques such as amniocentesis.

Molecular allelokaryotyping of T-cell prolymphocytic leukemia cells with high density single nucleotide polymorphism arrays identifies novel common genomic lesions and acquired uniparental disomy.

BACKGROUND: T-cell prolymphocytic leukemia is a rare aggressive lymphoproliferative disease with a mature T-cell phenotype and characteristic genomic lesions such as inv(14)(q11q34), t(14;14)(q11;q32) or t(X;14)(q28;q11), mutation of the ATM gene on chromosome 11 and secondary alterations such as deletions of chromosome 8p and duplications of 8q. DESIGN AND METHODS: We analyzed malignant cells from 18 patients with T-cell prolymphocytic leukemia using high density 250K single nucleotide polymorphism arrays and molecular allelokaryotyping to refine understanding of known alterations and identify new target genes. RESULTS: Our analyses revealed that characteristic disruptions of chromosome 14 are frequently unbalanced. In the commonly deleted region on chromosome 11, we found recurrent microdeletions targeting the microRNA 34b/c and the transcription factors ETS1 and FLI1. On chromosome 8, we identified genes such as PLEKHA2, NBS1, NOV and MYST3 to be involved in breakpoints. New recurrent alterations were identified on chromosomes 5p, 12p, 13q, 17 and 22 with a common region of acquired uniparental disomy in four samples on chromosome 17q. Single nucleotide polymorphism array results were confirmed by direct sequencing and quantitative real-time polymerase chain reaction. CONCLUSIONS: The first high density single nucleotide polymorphism array allelokaryotyping of T-cell prolymphocytic leukemia genomes added substantial new details about established alterations in this disease and moreover identified numerous new potential target genes in common breakpoints, deletions and regions of acquired uniparental disomy.

Haploinsufficiency of CDKN1B contributes to leukemogenesis in T-cell prolymphocytic leukemia.

T-cell prolymphocytic leukemia (T-PLL) is consistently associated with inactivation of the ATM gene and chromosomal re-arrangements leading to an overexpression of MTCP1/TCL1 oncoproteins. These alterations are present at the earliest stage of malignant transformation, suggesting that additional events are required for overt malignancy. In this study, we pursued the investigation of the 12p13 deletion, previously shown to occur in approximately half of T-PLLs. We refined the minimal region of deletion by single nucleotide and microsatellite polymorphism allelotyping. We defined a 216-kb region containing the CDKN1B gene that encodes the cyclin-dependent kinase inhibitory protein p27(KIP1). Sequencing this gene in 47 T-PLL patient samples revealed a nonsense mutation in one case without 12p13 deletion. The absence of biallelic inactivation of CDKN1B for most patients suggested a haploinsufficiency mechanism for tumor suppression, which was investigated in an animal model of the disease. In a Cdkn1b(+/-) background, MTCP1 transgenics had consistent and multiple emergences of preleukemic clones not observed in control cohorts. The second Cdkn1b allele was maintained and expressed in these preleukemic clones. Altogether, these data strongly implicate CDKN1B haploinsufficiency in the pathogenesis of T-PLL.

The TCL1 oncoprotein inhibits activation-induced cell death by impairing PKCtheta and ERK pathways.

The TCL1/MTCP1 oncogenes were identified on the basis of their involvement in T-cell prolymphocytic leukemia (T-PLL). TCL1 and MTCP1 proteins directly interact with AKT and modulate the AKT signal-transduction pathway, but the relevance of this mechanism in leukemogenesis remains unclear. We investigate the biologic functions of TCL1 in the T-cell lineage using various cell lines, and primary malignant and normal lymphocytes. In the Jurkat cell line, expression of TCL1 had no effect in unstimulated cells, whereas it abrogated activation-induced cell death (AICD). These cellular effects were concomitant with a major inhibition by TCL1 of PKCtheta and ERK pathways. Secondly, the TCL1-driven T-cell leukemia cell line SUP-T11 was shown to have impaired PKCtheta and ERK phosphorylation upon stimulation, which were restored by TCL1 inhibition using RNA interference. Finally, defects in these pathways were also observed in primary malignant (T-PLL) and transduced normal T lymphocytes expressing TCL1. Altogether, our data demonstrated that TCL1 inhibits AICD in T cells by blocking PKCtheta and ERK activation, upon cellular activation.