Duffy blood group gene polymorphisms among malaria vivax patients in four areas of the Brazilian Amazon region

<p>Abstract</p> <p>Background</p> <p>Duffy blood group polymorphisms are important in areas where <it>Plasmodium vivax </it>predominates, because this molecule acts as a receptor for this protozoan. In the present study, Duffy blood group genotyping in <it>P. vivax </it>malaria patients from four different Brazilian endemic areas is reported, exploring significant associations between blood group variants and susceptibility or resistance to malaria.</p> <p>Methods</p> <p>The <it>P. vivax </it>identification was determined by non-genotypic and genotypic screening tests. The Duffy blood group was genotyped by PCR/RFLP in 330 blood donors and 312 malaria patients from four Brazilian Amazon areas. In order to assess the variables significance and to obtain independence among the proportions, the Fisher's exact test was used.</p> <p>Results</p> <p>The data show a high frequency of the <it>FYA/FYB </it>genotype, followed by <it>FYB/FYB, FYA/FYA</it>, <it>FYA/FYB-33 </it>and <it>FYB/FYB-33</it>. Low frequencies were detected for the <it>FYA/FY</it>^<it>X</it>, <it>FYB/FY</it>^<it>X</it>, <it>FYX/FY</it>^{<it>X </it>}and <it>FYB-33/FYB-33 </it>genotypes. Negative Duffy genotype (<it>FYB-33/FYB-33</it>) was found in both groups: individuals infected and non-infected (blood donors). No individual carried the <it>FY</it>^<it>X</it><it>/FYB-33 </it>genotype. Some of the Duffy genotypes frequencies showed significant differences between donors and malaria patients.</p> <p>Conclusion</p> <p>The obtained data suggest that individuals with the <it>FYA/FYB </it>genotype have higher susceptibility to malaria. The presence of the <it>FYB-33 </it>allele may be a selective advantage in the population, reducing the rate of infection by <it>P. vivax </it>in this region. Additional efforts may contribute to better elucidate the physiopathologic differences in this parasite/host relationship in regions endemic for <it>P. vivax </it>malaria, in particular the Brazilian Amazon region.</p

HLA molecule expression on the surface of cells and microparticles in platelet concentrates

International audienceBackground: Platelet (PLT) transfusions are an essential treatment for bleeding disorders. However, immunologic complications can occur, including alloantibody production against Class I HLA molecules. The principal source of HLA molecules in PLT concentrates (PCs) is the PLTs themselves. However, extracellular microparticles (MPs) present in PCs may express HLA molecules.Study design and methods: We used nanoscale flow cytometry to explore the expression of HLA-A2, HLA-B7, and HLA-B57 on the surface of cells, PLT-derived MPs (PMPs), lymphocyte-derived MPs (LMPs), and monocyte-derived MPs (MMPs) present in PCs. Expression was studied during 7 days of storage.Results: Platelets were not the only source of HLA molecules in PCs. HLA molecules were present on PMPs, LMPs, and MMPs. The level of HLA Class I molecule expression varied between haplotypes and MPs of different origins and during storage.Conclusion: Platelets or residual cells remaining after leukoreduction are not the only source of HLA Class I molecules in PCs, highlighting the contribution of MPs to alloimmunization mechanisms. These data may be relevant for the development of new transfusion guidelines

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

International audienceBackground: 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

Positive association of DRB1*04 and DRB1*15 alleles with Fya immunization in a Southern European population

BACKGROUND: Anti-Fya has been implicated in hemolytic transfusion reactions. However, not all Fy(a-) patients develop anti-Fya after transfusion with 1 unit of blood [Fy(a+)]. This study was designed to identify HLA-DRB1 alleles associated with a predisposition to Fya immunization after blood transfusion. STUDY DESIGN AND METHODS: To identify HLADRB1 alleles prone to immunization after blood transfusion or pregnancy, HLA-DRB1 genotyping using polymerase chain reaction with sequence-specific oligonucleotide nonradioactive probe/sequence-specific priming methods was performed on blood samples from 67 immunized patients and 200 unrelated controls from the same southern European population in a casecontrol retrospective study. RESULTS: Ninety-six percent of patients with anti-Fya had at least one HLA-DRB1*04 or HLA-DRB1*15 allele compared to 34% of controls (pc < 0.001). Furthermore HLA-DRB1*04 and HLA-DRB1*1501 frequencies were significantly increased in Fya-immunized patients (35% vs. 12%, pc < 0.001; and 30% vs. 19%, pc < 0.001, respectively). Among HLA-DRB1*04 allelic subtypes, DRB1*0401 and DRB1*0403 alleles were more strongly correlated with Fya immunization (51% vs. 24% and 19% vs. 9%; pc < 0.001, respectively). CONCLUSIONS: This study indicated that HLADRB1* 04 and DRB1*1501 are overrepresented in Fyaimmunized patients. The correlation between these alleles and Fya immunization could be due to a particular presentation of the Fya peptide in HLA-DRB1 molecules

Phenotypic differences of CD4 + T cells in response to red blood cell immunization in transfused sickle cell disease patients

International audienceAlloimmunization against red blood cells (RBCs) is the main immunological risk associated with transfusion in patients with sickle cell disease (SCD). However, about 50-70% of SCD patients never get immunized despite frequent transfusion. In murine models, CD4(+) T cells play a key role in RBC alloimmunization. We therefore explored and compared the CD4(+) T-cell phenotypes and functions between a group of SCD patients (n = 11) who never became immunized despite a high transfusion regimen and a group of SCD patients (n = 10) who had become immunized (at least against Kidd antigen b) after a low transfusion regimen. We studied markers of CD4(+) T-cell function, including TLR, that directly control lymphocyte function, and their spontaneous cytokine production. We also tested responders for the cytokine profile in response to Kidd antigen b peptides. Low TLR2/TLR3 expression and, unexpectedly, strong expression of CD40 on CD4(+) T cells were associated with the nonresponder status, whereas spontaneous expression of IL-10 by CD4(+) T cells and weak Tbet expression were associated with the responder status. A Th17 profile was predominant in responders when stimulated by Jb(k) . These findings implicate CD4(+) T cells in alloimmunization in humans and suggest that they may be exploited to differentiate responders from nonresponders

Dominant immune response to HLA‐B57/B58 molecules after platelet transfusion

International audienceBackground: Patients with hematologic malignancies require prophylactic or curative platelet transfusions to prevent or treat bleeding. Treatments such as chemotherapy, radiotherapy, and hematopoietic stem cell transplantation cause persistent thrombocytopenia, necessitating platelet transfusions. However, class I HLA antibodies can cause a serious complication: immune-mediated platelet refractoriness. The mechanisms of alloimmunization are incompletely understood. We explored the immunogenicity of HLA molecules and the phenotype of the HLA-specific CD4+ T cells involved in alloimmunization.Study design and methods: We investigated the role of HLA molecules in platelet transfusion immunogenicity in a retrospective cohort study on men with specific anti-HLA who had undergone transfusion. We investigated the presence and phenotypic profile of HLA-specific CD4+ T cells in alloimmunized patients included in long-term platelet transfusion programs for hematologic malignancies.Results: More than 50% of the transfused subjects displayed an antibody response against HLA-B57 or -B58. HLA-B57-specific CD4+ T-cell responses were observed in patients alloimmunized against HLA-B57. Following specific stimulation, the patients presented HLA-specific CD4+ T cells producing tumor necrosis factor-α, interleukin (IL)-13, IL-17A, IL-2, IL-10, and IL-21.Conclusion: These results shed light on posttransfusion class I anti-HLA alloimmunization mechanisms and constitute a first step toward developing new strategies for reducing refractoriness