Mutational analysis of JAK2, CBL, RUNX1, and NPM1 genes in familial aggregation of hematological malignancies.

Familial aggregation of hematological malignancies has been reported highlighting inherited genetic predisposition. In this study, we targeted four candidate genes: JAK2 and RUNX1 genes assuring a prominent function in hematological process and CBL and NPM1 as proto-oncogenes. Their disruption was described in several sporadic hematological malignancies. The aim of this study is to determine whether JAK2, CBL, RUNX1, and NPM1 germline genes mutations are involved in familial hematological malignancies. Using direct sequencing, we analyzed JAK2 (exons 12 and 14); CBL (exons 7, 8 and 9); NPM1 (exon 12) and the entire RUNX1 in 88 independent families belonging to Tunisian and French populations. Twenty-one sporadic acute leukemias were included in this study. We reported a heterozygous intronic c.1641 + 6 T > C JAK2 variant (rs182123615) found in two independent familial cases diagnosed with gastric lymphoma and Hodgkin lymphoma. The in silico analysis suggested a potential impact on splicing, but the functional splicing minigene reporter assay on rs182123615 variant showed no aberrant transcripts. In one sporadic acute myeloblastic leukemia, we reported an insertion 846 in. TGTT in exon 12 of NPM1 gene that may impact the normal reading frame. The rs182123615 JAK2 variant was described in several contexts including myeloproliferative neoplasms and congenital erythrocytosis and was supposed to be pathogenic. Through this current study, we established the assessment of pathogenicity of rs182123615 and we classified it rather as rare polymorphism.

(C)ce(s) haplotype screening in Tunisian blood donors.

BACKGROUND: The (C)ce(s) haplotype, mainly found in black individuals, contains two altered genes: a hybrid RHD-CE-D(s) gene segregated with a ce(s) allele of RHCE with two single nucleotide polymorphisms, c. 733C>G (p.Leu245Val) in exon 5 and c. 1006G>T (Gly336Cys) in exon 7. This haplotype could be responsible for false positive genotyping results in RhD-negative individuals and at a homozygous level lead to the loss of a high incidence antigen RH34. The aim of this study was to screen for the (C)ce(s) haplotype in Tunisian blood donors, given its clinico-biological importance. MATERIAL AND METHODS: Blood samples were randomly collected from blood donors in the blood transfusion centre of Sousse (Tunisia). A total of 356 RhD-positive and 44 RhD-negative samples were tested for the (C)ce(s) haplotype using two allele-specific primer polymerase chain reactions that detect c. 733C>G (p.Leu245Val) and c. 1006G>T (p. Gly336Cys) substitutions in exon 5 and 7 of the RHCE gene. In addition, the presence of the D-CE hybrid exon 3 was evaluated using a sequence-specific primer polymerase chain reaction. RESULTS: Among the 400 individuals only five exhibited the (C)ce(s) haplotype in heterozygosity, for a frequency of 0.625%. On the basis of the allele-specific primer polymerase chain reaction results, the difference in (C)ce(s) haplotype frequency was not statistically significant between RhD-positive and RhD-negative blood donors. DISCUSSION: These data showed the presence of the (C)ce(s) haplotype at a low frequency (0.625%) compared to that among Africans in whom it is common. Nevertheless, the presence of RHD-CE-D(s) in Tunisians, even at a lower frequency, should be considered in the development of a molecular genotyping strategy for Rh genes, to ensure better management of the prevention of alloimmunisation.

Molecular study of the perforin gene in familial hematological malignancies.

Perforin gene (PRF1) mutations have been identified in some patients diagnosed with the familial form of hemophagocytic lymphohistiocytosis (HLH) and in patients with lymphoma. The aim of the present study was to determine whether patients with a familial aggregation of hematological malignancies harbor germline perforin gene mutations. For this purpose, 81 unrelated families from Tunisia and France with aggregated hematological malignancies were investigated. The variants detected in the PRF1 coding region amounted to 3.7% (3/81). Two of the three variants identified were previously described: the p.Ala91Val pathogenic mutation and the p.Asn252Ser polymorphism. A new p.Ala 211Val missense substitution was identified in two related Tunisian patients. In order to assess the pathogenicity of this new variation, bioinformatic tools were used to predict its effects on the perforin protein structure and at the mRNA level. The segregation of the mutant allele was studied in the family of interest and a control population was screened. The fact that this variant was not found to occur in 200 control chromosomes suggests that it may be pathogenic. However, overexpression of mutated PRF1 in rat basophilic leukemia cells did not affect the lytic function of perforin differently from the wild type protein.