The Spectrum of ß-Thalassemia Mutations in a Population from the Brazilian Amazon.

The spectrum of ß-thalassemia (ß-thal) mutations was investigated for the first time in a cohort of 33 unrelated patients from the Brazilian Amazon attending the Center for Hemotherapy and Hematology of the Pará Foundation (HEMOPA), in Belém, the state capital of Pará, Northern Brazil. Identification of the ß-thal mutations was made by direct genomic sequencing of the ß-globin gene. Mutations were identified in all patients, corresponding to a spectrum of 10 different point mutations and a total of 37 alleles studied. HBB: c.92 + 5G > A [IVS-I-5 (G > A)], was the most common ß-thal mutation, followed by HBB: c.118C > T [codon 39 (C > T)], HBB: c.-138C > T [-88 (C>T)], HBB: c.92 + 1G > A [IVS-I-1 (G > A)] and HBB: c.92 + 6T > C [IVS-I-6 (T > C)] mutations. These five mutations (four Mediterranean origin and one African origin) accounted for 86.5% of the ß-thal alleles. The profile of ß-thal mutations found in northern Brazil is different from those described in other regions of the country. In the southeast and south, the nonsense mutation HBB: c.118C > T is the most prevalent, followed by HBB: c.93-21G > A [IVS-I-110 (G > A)], whereas in the northeast, HBB: c.92 + 6T > C has been identified as the most common mutation, followed by HBB: c.92 + 1G > A. This heterogeneous geographical distribution is certainly related to the ancestry of Brazilian populations because they have similar genetic backgrounds (European, African and Amerindian), although with slightly different admixture proportions. Furthermore, the European contribution in the southeast and south was largely made up of immigrants of other nationalities, such as Italian and Spanish, in addition to Portuguese.

Plasmodium vivax infection in Anajás, State of Pará: no differential resistance profile among Duffy-negative and Duffy-positive individuals.

BACKGROUND: There is large body of evidence that states that invasion of Plasmodium vivax requires the Duffy antigen, but the universality of this specificity is certainly now under question with recent reports showing that in some parts of the world P. vivax infects and causes disease in Duffy-negative people. These findings reinforce the idea that this parasite is rapidly evolving, being able to use other receptors than Duffy to invade the erythrocytes, which may have an enormous impact in P. vivax current distribution. The presence of P. vivax infection in Duffy-negative individuals was investigated in a cross-sectional study conducted in Anajás, Archipelago of Marajó, State of Pará, which is an area of malaria transmission in the Brazilian Amazonia. METHODS: Duffy genotyping and Plasmodium species diagnostic assays were performed successfully in 678 individuals. An allele-specific primer polymerase chain reaction (PCR) technique was used for Duffy blood group genotyping. Identification of Plasmodium species was achieved by conventional blood smear light microscopy and a TaqMan-based real-time PCR method to detect mitochondrial genome of Plasmodium falciparum and P. vivax. RESULTS: Plasmodium spp. infection was detected in 137 samples (20.2%). Prevalence of each Plasmodium species was 13.9% P. vivax, 5.8% P. falciparum, and 0.6% P. vivax plus P. falciparum. Overall, 4.3% (29/678) were genotyped as Duffy-negative (FY*BES/*BES). Among Duffy-negative individuals 6.9% were P. vivax PCR positive and among Duffy-positive 14.2% were P. vivax PCR positive. Although lower, the risk of Duffy-negatives to experience a P. vivax blood stage infection was not significantly different to that of Duffy-positives. Furthermore, the genotypic and allelic frequencies of the Duffy blood group among P. vivax-infected patients and in the control group did not differ significantly, also suggesting no reduction in infection rates among the carriers of FY*BES allele. CONCLUSIONS: The data obtained in Anajás showed no differential resistance vivax malaria among Duffy-negative and Duffy-positive individuals. This result needs additional confirmation through a deeper evaluation in a larger sample of patients with P. vivax malaria and molecular parasite characterization. Nonetheless, this genetic profile of the parasite may be contributing to the high incidence of malaria in the municipality.

Importância da avaliação da hemoglobina fetal na clínica da anemia falciforme / The importance of the evaluation of fetal hemoglobin in the clinical assessment of sickle cell disease

A anemia falciforme está entre as doenças genéticas mais comuns e mais estudadas em todo o mundo. Ela é causada por mutação no gene β, produzindo alteração estrutural na molécula da hemoglobina. As moléculas de HbS, decorrentes da mutação, sofrem processo de polimerização fisiologicamente provocado pela baixa tensão de oxigênio, acidose e desidratação. Com isso, os eritrócitos passam a apresentar a forma de foice, causando vaso-oclusão e outras conseqüências. O objetivo desse estudo foi revisar a importância da hemoglobina fetal na clínica de pacientes portadores de anemia falciforme. O significado clínico da associação da elevação da hemoglobina fetal na anemia falciforme mostra-se favorável em termos hematológicos, pois, nessa interação, as células-F têm baixas concentrações de HbS e, com isso, inibem a polimerização da HbS e a alteração da morfologia dos eritrócitos. O tratamento com hidroxiuréia, em função do aumento na expressão da hemoglobina fetal que este fármaco proporciona, traz aos pacientes falcêmicos uma melhora significativa em sua clínica. Portanto, a hemoglobina fetal consiste no maior inibidor da polimerização da desoxi-HbS e, com isso, evita a falcização do eritrócito, a anemia hemolítica crônica, as crises dolorosas vaso-oclusivas, o infarto e a necrose em diversos órgãos, melhorando a clínica e a expectativa de vida dos pacientes.

Sickle cell disease is one of the commonest and most studied genetic diseases in the world. Caused by a mutation of the β gene, it changes the molecular structure of hemoglobin. Abnormal Hb S molecules suffer polymerization physiologically provoked by a low oxygen tension, acidosis and dehydration. As a result, red blood cells take on a sickle cell form, which causes microvascular occlusion with varying consequences. The objective of this study was to review the importance of fetal hemoglobin in the clinical assessment of sickle cell disease patients. It has been shown that the association of high levels of fetal hemoglobin with sickle cell disease is favorable in hematological terms. In this interaction, F cells have low Hb S concentrations and thus inhibit Hb S polymerization and the morphological alteration of red blood cells. Treatment with hydroxyurea resulting in an increased fetal hemoglobin expression brings about a significant improvement in the patient's clinical state. Thus, fetal hemoglobin constitutes the greatest inhibitor of desoxi-Hb S polymerization and avoids the morphological alteration of red blood cells, chronic hemolytic anemia, painful microvascular occlusive crises, bone infarction and necrosis of several organs thereby improving the clinical outcome and the patients' life expectancy.