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B-, T-, and NK-cell lineage involvement in JAK2^V617F-positive patients with idiopathic myelofibrosis

Department of Hematology, University of Florence, Florence, Italy

Correspondence: Alessandro Maria Vannucchi, Department of Hematology, University of Florence, 50134 Florence, Italy. E-mail: amvannucchi{at}unifi.it

	ABSTRACT

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An acquired JAK2^V617F mutation has been found in myeloid cells from most patients with chronic idiopathic myelofibrosis (IM), but whether it occurs in a common myelo-lymphoid, rather than a myeloid-restricted, progenitor cell is still debated. Using a sensitive ARMS assay for the quantitative assessment of JAK2^V617F cDNA, we detected the mutation in purified B, T and NK cells from about half of 12 patients studied. These results indicate that involvement of the lymphoid lineage in IM may be more frequent than previously supposed.

Key words: JAK2, idiopathic myelofibrosis, myeloproliferative disease, stem cells, .

Patients with chronic myeloproliferative disorders (MPD) harbor a recurrent JAK2^V617F mutation¹ that has been consistently found in their granulocytes but not in control tissues. In cases in which T lymphocytes were analyzed, they resulted uniformly wild-type;^2,3 likewise, the mutation could not be found in CD19⁺ cells purified from three homozygous cases of MPD using a direct sequencing approach.⁴ These data would suggest that the cell target for the JAK2^V617Fmutation is a myeloid-restricted progenitor. However, this idea is challenged by the finding that cells with the hematopoietic stem cell (HSC) phenotype (CD34⁺, CD38^–, CD90⁺, Lin^–) from patients with polycythemia vera (PV) actually harbored the mutation. ⁵ Furthermore, Ishii et al.⁶ recently reported that B and T cells from, respectively, 2/8 and 1/8 PV patients were JAK2^V617F mutated. Interestingly, the mutation was also found in B, T, and NK cells of one patient with familial MPD.⁷

We analyzed 12 patients with IM, at variable times from diagnosis, searching for the presence of the JAK2^V617F mutation in their lymphoid cells. All patients gave informed consent to these investigations. Peripheral blood (PB) granulocytes were collected by density gradient centrifugation to 95% purity by visual inspection of cytosmears; CD3⁺ and CD19⁺ lymphocytes were obtained by direct immunomagnetic selection to a purity 98% by FACS re-analysis. In five patients, the purity of CD56⁺/CD3^– NK cells and CD3⁺/CD56^– T-lymphocytes obtained using an immunomagnetic depletion procedure was 93% and 95%, respectively. PB CD34⁺ cells were purified to 97% by direct immunomagnetic selection (Miltenyi Biotec, Germany). The percentage of JAK2^V617F cDNA in these cell fractions was measured using an ARMS procedure.⁸ Briefly, RNA was reverse transcribed and amplified using fluorochrome-labeled mutation-specific primers; amplicons were resolved by capillary electrophoresis, and the ratio of JAK2^V617F to JAK2^total (JAK2^V617F+JAK2^WT) cDNA was calculated.⁸

We observed a significant, although heterogeneous, pattern of lymphoid cell involvement in IM patients (Table 1). In particular, the JAK2^V617F mutation was detected in the CD19⁺ cells of 7/12 patients (58%), in the CD3⁺ cells of 5/12 (42%), and in the CD56⁺ NK cells of all the five cases in which they were evaluated. Remarkably, the JAK2^V617F ratio measured in these highly-purified lymphoid cell preparations was high enough, when compared to the corresponding value in granulocytes, to exclude the possibility that the presence of the mutation may have been due to a few contaminating granulocytes. The presence of the JAK2^V617F mutation in lymphoid cells was not obviously associated with the highest mutational load in myeloid cells; for example, patient #1 had a JAK2^V617F ratio of 100% in granulocytes, while both CD9⁺ and CD3⁺ were wild-type, and conversely patient #8, in whom a JAK2^V617F ratio of 26% was found in granulocytes, had a ratio of 30% in CD19⁺ cells and wild-type CD3⁺. Patient #11, who had a 6-year long history of the disease, was particularly interesting and presented a 100% ratio in all the different cell fractions examined.

Overall, the current data are in line with those recently reported by Delhommeau et al.⁹ in ten IM patients. These authors found the JAK2^V617F mutation in B-cells of 60% of the patients, in 25% in case of T-cells, and 63% of NK cells. The variable frequency of lymphoid cells involved in the JAK2^V617F mutant clone might be also explained by the long lifespan of these cells, especially T-lymphocytes, most of which actually pre-existed the event(s) leading to the acquisition of the JAK2^V617F mutation. Consistently, JAK2^V617F mutant T cells were found in all IM (and PV) patients evaluated using the fetal thymus organ culture (FTOC) assay.⁹

Larger studies are clearly needed to obtain a consistent figure of the incidence of JAK2^V617F mutation in lymphoid cells, but from these data it appears to be not sporadic; specifically, the low-sensitivity direct sequencing approach employed in the first studies might have been the reason for the under-estimation of this phenomenon. ^2–4 The consequences, if any, of the involvement of B cells, T cells and NK cells by the JAK2^V617F mutation are totally unclear so far, but one is tempted to speculate that it might underlie some of the immunologic abnormalities manifested by a significant proportion of IM patients.¹⁰

	References

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