JAK2-mutated Essential Thrombocythemia Research Articles

Transformation into acute myeloid leukemia with t(8;21)(q22;q22.1); RUNX1::RUNX1T1 from JAK2-mutated essential thrombocythemia: a case report

BackgroundBlast transformation is a rare but well-recognized event in Philadelphia-negative myeloproliferative neoplasms associated with a poor prognosis. Secondary acute myeloid leukemias evolving from myeloproliferative neoplasms are characterized by a unique set of cytogenetic and molecular features distinct from de novo disease. t(8;21) (q22;q22.1); RUNX1::RUNX1T1, one of the most frequent cytogenetic abnormalities in de novo acute myeloid leukemia, is rarely observed in post-myeloproliferative neoplasm acute myeloid leukemia. Here we report a case of secondary acute myeloid leukemia with t(8;21) evolving from JAK2-mutated essential thrombocythemia.Case presentationThe patient was a 74-year-old Japanese woman who was referred because of thrombocytosis (platelets 1046 × 109/L). Bone marrow was hypercellular with increase of megakaryocytes. Chromosomal analysis presented normal karyotype and genetic test revealed JAK2 V617F mutation. She was diagnosed with essential thrombocythemia. Thrombocytosis had been well controlled by oral administration of hydroxyurea; 2 years after the initial diagnosis with ET, she presented with leukocytosis (white blood cells 14.0 × 109/L with 82% of blasts), anemia (hemoglobin 91 g/L), and thrombocytopenia (platelets 24 × 109/L). Bone marrow was hypercellular and filled with 80% of myeloperoxidase-positive blasts bearing Auer rods. Chromosomal analysis revealed t(8;21) (q22;q22.1) and flow cytometry presented positivity of CD 13, 19, 34, and 56. Molecular analysis showed the coexistence of RUNX1::RUNX1T1 chimeric transcript and heterozygous JAK2 V617F mutation in leukemic blasts. She was diagnosed with secondary acute myeloid leukemia with t(8;21)(q22;q22.1); RUNX1::RUNX1T1 evolving from essential thrombocythemia. She was treated with combination chemotherapy with venetoclax and azacytidine. After the first cycle of the therapy, blasts disappeared from peripheral blood and decreased to 1.4% in bone marrow. After the chemotherapy, RUNX1::RUNX1T1 chimeric transcript disappeared, whereas mutation of JAK2 V617F was still present in peripheral leukocytes.ConclusionsTo our best knowledge, the present case is the first one with JAK2 mutation preceding the acquisition of t(8;21). Our result suggests that t(8;21); RUNX1::RUNX1T1 can be generated as a late event in the progression of JAK2-mutated myeloproliferative neoplasms. The case presented typical morphological and immunophenotypic features associated with t(8;21) acute myeloid leukemia.

Initiating-clone analysis in patients with acute myeloid leukemia secondary to essential thrombocythemia

Most of essential thrombocythemia (ET) patients have the clone harboring a mutation in one of the JAK2, CALR, or MPL gene, and these clones generally acquire additional mutations at transformation to acute myeloid leukemia (AML). However, the proliferation of triple-negative clones has sometimes been observed at AML transformation. To clarify the clonal evolution of ET to AML, we analyzed paired samples at ET and AML transformation in eight patients. We identified that JAK2-unmutated AML clones proliferated at AML transformation in three patients in whom the JAK2-mutated clone was dominant at ET. In two patients, TET2-mutated, but not JAK2-mutated, clones might be common initiating clones for ET and transformed AML. In a patient with JAK2-mutated ET, SMARCC2, UBR4, and ZNF143, but not JAK2, -mutated clones proliferated at AML transformation. Precise analysis using single-cell sorted CD34+/CD38- fractions suggested that ET clone with JAK2-mutated and AML clone with TP53 mutation was derived from the common clone with these mutations. Although further study is required to clarify the biological significance of SMARCC2, UBR4, and ZNF143 mutations during disease progression of ET and AML transformation, the present results demonstrate the possibility of a common initial clone involved in both ET and transformed AML.

Thrombotic and Bleeding Events in Japanese Adolescent and Young Adult PV and ET: Results from Japanese Multicenter Retrospective Study

[Background] There were no large-scale retrospective studies about adolescent and young adult (AYA) polycythemia vera (PV) or essential thrombocythemia (ET) in Japan. The characteristics in AYA PV or ET in Asia are not well-reported, except for one retrospective study using the Health Insurance Review and Assessment Service database in Korea. To reveal the clinical features, especially with regard to thrombotic and bleeding events in Japanese AYA PV and ET, we decided to perform secondary data analysis of Japanese multicenter large registry data, JSH-MPN-R18. [Methods] Data of PV and ET aged 20 to 39 at the initial visit were extracted from registration data in JSH-MPN-R18 as AYA cohort, and were compared to non-AYA cohort over 40 years old. Differences among categorical and continuous variables were evaluated by chi-square test or Fisher's exact test, and by Mann-Whitney U test, respectively. [Results] 31 PV (median age; 33 years［range 26-39］, male/female; 19/12) and 141 ET (median age; 32 years［range 20-39］, male/female; 52/89) were identified as AYA cohort, which represented 5.2% and 12.2% of overall PV or ET cohort, respectively. Non-AYA cohort consisted of 565 PV and 1011 ET. Regarding laboratory parameters, neutrophil ratio and counts were lower in AYA PV than in non-AYA PV, whereas, leukocyte counts, neutrophil ratio and counts, LDH and D-dimer level were lower in AYA ET than in non-AYA ET. The frequency of JAK2 V617F-mutated patients was lower in AYA than in non-AYA PV and ET (PV; 61.2% vs.77.2%, p=0.05, ET; 46.0% vs. 57.8%, p<0.01). Regarding the treatment, antiplatelet or anticoagulant therapy was introduced into 61.3% of AYA PV and 51.8% of AYA ET patients. Cytoreductive therapy (CRT) was provided to eight (25.8%) AYA PV and 61 (43.3%) AYA ET. In 62.5% of AYA PV and 75.4% of AYA ET, who received CRT, CRT was adopted for the reasons except for the past or recent thrombotic events (TE)/bleeding events. AYA PV patients experienced only one pulmonary embolism before diagnosis and one lacunar cerebral infarction (CI) at diagnosis. There were no TE after diagnosis in AYA PV. In terms of bleeding events, AYA PV had one event (details unknown) before diagnosis and two events (gastrointestinal bleeding and details unknown) after diagnosis. The frequency of AYA PV patients with TE had a tendency to be lower than that of non-AYA PV (6.5% vs 19.1%, p=0.09), although there were no statistical differences between the numbers of bleeding events between AYA and non-AYA PV during all of the course. AYA ET had nine TE (3 CI, 2 deep vein thrombosis (DVT), 1 transient ischemic attack (TIA), 1 peripheral arterial disease (PAD), 2 details unknown) before diagnosis, six TE (3 DVT, 2 CI, 1 TIA) at diagnosis, and six TE (1 myocardial infarction, 1 CI, 1 PAD, 1 TIA, 2 details unknown) after diagnosis. Fewer TE occurred in AYA ET than in non-AYA ET before (6.4% vs 19.8%, p<0.01) and at diagnosis (4.3% vs 9.5%, p=0.04). However the frequency of TE was not different (4.3% vs. 6.7%, p=0.36) after diagnosis. AYA ET had experienced only one bleeding event (oral mucosal bleeding) before diagnosis. Bleeding events were never found at or after diagnosis. Fewer bleeding events were detected in AYA ET than non-AYA ET during all of the course (0.7% vs 8.6%, p<0.01). The percentage of venous TE in total TE was higher in AYA-MPN than in non-AYA MPN (26.1% vs 5.4%). [Conclusion] Our analysis is the first retrospective cohort which revealed clinical features related to TE and bleeding events in Asian AYA MPN from large multicenter registry data. Lower neutrophil ratio and absolute counts at diagnosis might be attributable to lower mutated JAK2 allele burden in AYA PV, and lower frequency of JAK2-mutated ET in AYA ET. Regarding bleeding events, fewer bleeding events were found in AYA ET than in non-AYA ET. However in PV, there were no statistical differences in bleeding events between AYA and non-AYA. About TE, AYA PV and ET had fewer TE than non-AYA PV and ET. The percentage of venous TE in total TE was higher in AYA MPN than in non-AYA MPN also in Japan, but it was much lower than those reported in previous European or US cohorts, in which venous TE were more common than arterial TE. Especially after diagnosis, venous TE were never detected in either AYA PV or ET in Japan. Considering that the frequency of venous TE in the Korean receipt data was as low as that in our cohort, fewer venous TE might be one of the specific characteristics in Asian AYA MPN different from European or US AYA MPN.

Unlike TET2 and ASXL1, Co-Occurring DNMT3A Mutations Are Not Associated with Increased Age in JAK2-Mutant Myeloproliferative Neoplasms (MPNs)

MPNs including essential thrombocythemia (ET), polycythemia vera (PV), and myelofibrosis (MF) are characterized by JAK2, CALR and MPL mutations. Additional mutations outside these driver genes also co-occur. To better understand interactions between phenotypic driver mutations and concomitant mutations, we evaluated patterns of somatic mutation acquisition in 1301 MPN (535 ET, 392 PV, 331 MF, and 43 MPN NOS) patients who underwent clinical next generation sequencing (NGS) at our institution. For this analysis, we focused on a single NGS panel obtained closest to MPN diagnosis. Median age at MPN diagnosis was 59 years, with MF patients older than ET/PV patients (p<4e-11). 67%, 17%, and 4.5% of patients had mutations in JAK2, CALR, or MPL. The average variant allele fraction (VAF) for JAK2, CALR and MPL was 48%, 34%, and 40%. 52% of patients had pathogenic mutations in an additional gene (range 0-7), most frequently TET2, DNMT3A, and ASXL1. PV patients were more likely to have a TET2 mutation compared with JAK2-mutated ET patients (42% vs 25%). Mutation combinations that occurred together more frequently than expected (p<1e-3) included DNMTA-TET2, ASXL1-TET2, ASXL1-DNMT3A, and ASXL1-SRSF2. We then investigated how these concomitant mutations interacted with the MPN driver mutation and each other. JAK2-mutatedMPN patients with no concomitant mutations were younger than JAK2-mutated patients with TET2 or ASXL1 mutations. In contrast, age distributions were similar between JAK2-only patients and those with JAK2 and DNMT3A mutations (Fig 1A). This observation held when looking within PV and ET, and whether patients with single or multiple concomitant mutations were considered. Since DNMT3A, TET2 and ASXL1 clonal hematopoiesis is associated with increasing age, the similar age distribution of JAK2-only and JAK2-DNMT3A co-mutant patients was an unexpected finding, and worthy of further study. We evaluated the fraction of JAK2-mutated patients with a given concomitant mutation as a function of age. The fraction of patients with TET2 and ASXL1 mutations increased with age, but not the fraction of patients with DNMT3A mutations (95% CI of slope: 4e-3 to 7e-3 for TET2, 0 to 3e-3 for DNMT3A). Similarly, when we evaluated the fraction of JAK2-mutated patients with a given concomitant mutation as a function of JAK2 VAF, the fraction of patients with TET2 and ASXL1 mutations increased as JAK2 VAF increased, but the fraction of patients with DNMT3A mutations decreased (Fig 1B; 95% CI of slope: 1e-3 to 3e-3 for TET2, -2e-3 to 0 for DNMT3A). One potential explanation for this is that JAK2 and DNMT3A mutations occur as independent clonal acquisitions and that the JAK2-mutant clone “out-competes” the DNMT3A-mutant clone over time. At JAK2 VAFs of 50% and 100%, the ratio of TET2:JAK2 VAFs clustered at 1.0 and 0.5, suggesting frequent presence of a dominant JAK2-TET2 clone in all cells with heterozygous or homozygous JAK2 mutations. ASXL1 mutations occurred mostly in patients with JAK2 VAF > 50%, consistent with it being a subclonal acquisition. In contrast, DNMT3A concomitant mutations were more likely to occur in patients with JAK2 VAF<50% vs >50%, again suggesting that DNMT3A clones diminish as JAK2 clones expand. 6/45 DNMT3A mutations that occurred as the sole concomitant mutation were R882 hotspot mutations. However, DNMT3A was more likely to co-occur at JAK2 VAF>50% in patients with >1 concomitant mutation (most commonly TET2). This suggests that in the context of JAK2-mutant driven MPNs, DNMT3A subclones may require the presence of an additional mutation to expand. In summary, we found DNMT3A mutations behave differently from TET2 and ASXL1 mutations in JAK2-mutant MPNs. Patients with JAK2-mutant MPN are less likely to have DNMT3A mutations as JAK2 VAF increases. Compared with TET2 or ASXL1, DNMT3A appears more likely to exist as an independent clone in JAK2-mutant MPN, with our data suggesting the JAK2-mutant clone exhibits increased fitness compared to the DNMT3A-mutantclone over time. However, DNMT3A mutations persist when accompanied by other concomitant mutations (particularly TET2). These results raise interesting questions regarding clonal competition in MPN. Since all our analyses were performed from single clinical NGS panels, our findings require additional validation, including with multi-gene single-cell genotyping, which we are currently pursuing.

Mutation Status Defines Subtypes of Essential Thrombocythemia and Relation to Polycythemia Vera in Iraqi Patients

Background: Polycythemia vera (PV) and essential thrombocythemia (ET) are a part of the BCR-ABL1-negative myeloproliferative neoplasms (MPNs) that harbor mutation in Janus kinase 2 (JAK2), CALR, or MPL gene. Objectives: The objective of this study was to investigate the impact of JAK2 and CALR mutations on the clinical course and hematological phenotype of ET patients and to evaluate the biological and clinical features of ET and PV sharing the same type of mutation in JAK2V617F. Materials and Methods: This was a cross-sectional study that included 94 patients diagnosed with MPN, of them 47 had PV and 47 had ET. JAK2V617F mutation was assessed using either allele-specific PCR or JAK-2 quantitative real-time PCR kit. JAK2-negative patients were further assessed for the existence of CALR mutations using SNP biotechnology MPN screening kit. Results: JAK2 mutation was identified in 29 ET patients, whereas CALR mutations were confirmed in 18 patients. JAK2-mutated ET patients were significantly older than those with CALR mutations. Seventy-six were reported to have a mutation in JAKV617F, of them 47 were diagnosed as PV and 29 as ET. JAK2V617F-mutated PV patients had significantly higher levels of hemoglobin, hematocrit, and WBC than JAK2-mutated ET patients. On the other hand, JAK2-mutated PV patients exhibited lower platelet count than ET harboring the same mutation. Conclusion: JAK2-mutated ET represents a distinct clinical entity that has a hematological and clinical phenotype ranging between JAK2-mutated PV and CALR-mutated ET. The analysis of the mutational status is essential in discriminating subtypes of MPN and confirming the diagnosis in ET and PV patients.

Classical Philadelphia-negative myeloproliferative neoplasms (MPNs): A continuum of different disease entities.

Classical Philadelphia-negative myeloproliferative neoplasms (MPNs) are clonal hematopoietic stem cell-derived disorders characterized by uncontrolled proliferation of differentiated myeloid cells and close pathobiologic and clinical features. According to the 2016 World Health Organization (WHO) classification, MPNs include polycythemia vera (PV), essential thrombocythemia (ET), and primary myelofibrosis (PMF). The 2016 revision aimed in particular at strengthening the distinction between masked PV and JAK2-mutated ET, and between prefibrotic/early (pre-PMF) and overt PMF. Clinical manifestations in MPNs include constitutional symptoms, microvascular disorders, thrombosis and bleeding, splenomegaly secondary to extramedullary hematopoiesis, cytopenia-related symptoms, and progression to overt MF and acute leukemia. A dysregulation of the JAK/STAT pathway is the unifying mechanistic hallmark of MPNs, and is guided by somatic mutations in driver genes including JAK2, CALR and MPL. Additional mutations in myeloid neoplasm-associated genes have been also identified, with established prognostic relevance, particularly in PMF. Prognostication of MPN patients relies on disease-specific clinical models. The increasing knowledge of MPN biology led to the development of integrated clinical and molecular prognostic scores that allow a more refined stratification. Recently, the therapeutic landscape of MPNs has been revolutionized by the introduction of potent, selective JAK inhibitors (ruxolitinib, fedratinib), that proved effective in controlling disease-related symptoms and splenomegaly, yet leaving unmet critical needs, owing the lack of disease-modifying activity. In this review, we will deal with molecular, clinical, and therapeutic aspects of the three classical MPNs aiming at highlighting either shared characteristics, that overall define a continuum within a single disease family, and uniqueness, at the same time.

Phenotypes of JAK2-Mutated Polycythemia Vera and Essential Thrombocythemia with and without Thromboembolic Events: Results of the Hinc-207 (OSHO #91) Study

Thrombosis is the major cause of morbidity and mortality in polycythemia vera (PV) and essential thrombocythemia (ET). Age ≥60 years (y) and/or history of thrombosis labels patients (pts) as high-risk for thrombosis. Yet, thrombosis frequently occurs prior to the diagnosis of PV/ET. In a multicenter study of the East German Study Group (HINC-207; OSHO #091), the interaction between age and time occurrence of the first thrombosis as risk factors for thrombosis after diagnosis was studied. Methods After IRB approvals, JAK2 mutated adults with PV or ET were prospectively enrolled in 9 centers and centrally stratified in a one to two ratio (group A: pts with a history of thrombosis; group B: pts without thrombosis) with a pre-planned minimum of 60:120 pts. Based on a longitudinal and cross-sectional design, clinical and laboratory data at diagnosis, last follow-up, and thrombosis (for group A) were collected. Thrombosis prior to diagnosis was labeled as A1 and thrombosis after diagnosis as A2. Thrombosis risk factors were grouped into age-, previous thrombosis-, thrombosis prior to PV/ET-, cardiovascular (CV)-, thrombophilia-, and disease- (JAK2 allele burden, Hct, and WBC) related. Additionally, therapies [aspirin (ASS), anticoagulation, phlebotomy, and cytoreduction] and data from a study-own patient questionnaire were included. All pts signed informed consent. The primary endpoint was the phenotypic diversity in JAK2-mutated ET and PV pts with or without thrombosis. Results From April to Dec, 2019, 246 pts were recruited. Data on 237 pts (median age 62y; 59% females, 58% PV) are available. At diagnosis, pts in group A (n=71, median age 59.5y) tended to be younger than those in group B (n=166, median age 63y) (p=0.07). Yet, 70.4% thrombotic events (venous: median age 46.5y; arterial: median age 57y) occurred in A1 and correlated with younger age (p=0.03). Only 3 pts developed a second event after diagnosis. These were counted in A2 (n=24, median age at thrombosis: 61y). Overall, thrombosis occurred either prior to or within the first 3y after diagnosis in 63/71 (89%) pts. Age>60y could not be identified as a risk factor for thrombosis or type of thrombosis at any time point. The 5 y probability of no thrombotic event after diagnosis in pts >60y was 90.4% vs. 89.2% for pts <60y (p=0.8) and that of a thrombotic event >3y after diagnosis in pts >60y was 3.7% vs. 4.9% for pts <60y (p=0.7). Similarly, A1 did not correlate with A2 (p=0.3). With 1691 patient-years for the entire cohort, the incidence of thrombosis after PV/ET diagnosis was 0.7 for arterial and 0.6 for venous events per 100 patient-years. Smoking was more prevalent in pts >60y (p=0.003) and was not associated with thrombosis. Irrespective of age, hypertension (65%, p=0.03), hyperlipidemia (19%, p=0.008), and diabetes (16.4%, p=0.05) were frequent and correlated with A2 while atrial fibrillation (p=0.03) and inherited thrombophilia risk factors (p<0.00) with A1. JAK2 allele burden (median 19%) and Hct >45% (median 45%) at diagnosis correlated strongly with age >60y (p=0.005) but not with A, A1, or A2, although Hct >45% at diagnosis correlated with A2 in PV (p=0.001). Surprisingly, a Hct >45% at thrombosis was more frequently present in A1 (55%) vs A2 (30%) (p<0.00). Median WBC at diagnosis was higher in B compared to A (p=0.004), strongly associated with age >60y (p<0.00) but not with A2. WBC >15% at thrombosis did not correlate with A. Age rather than thrombosis was the trigger for cytoreduction [82% hydroxyurea (HU) in B pts >60y vs 53% in A pts <60y] (p<0.00). In PV, ASS did not correlate with thrombosis (25% of pts in B did not receive ASS). Cytoreduction, interval between diagnosis and cytoreduction, nor the duration of exposure correlated with thrombosis. Conclusions: The majority of thrombotic events occurred prior to or within the first 3 years after the diagnosis of JAK2 mutated PV/ET and were associated with CV-risk factors rather than older age. Phenotypic features such as Hct >45%, high WBC, and JAK2 allele burden were associated with age >60y and less with thrombosis. Their value as surrogate markers for therapeutic interventions to reduce thrombosis needs to be critically evaluated in larger series. Whether adequate PV/ET- or CV-risk- treatments account for the low rate of CV events after diagnosis (despite a higher incidence of CV-risk factors) compared to the general population could not be answered due to study design and needs to be addressed prospectively. Disclosures Al-Ali: Novartis: Honoraria, Research Funding; Celgene: Honoraria, Research Funding.

A Case of Essential Thrombocythemia and IgA Nephropathy with Literature Review of the Concurrence

Myeloproliferative neoplasms such as essential thrombocythemia (ET) have been associated with glomerular disease on rare instances. A case of ET associated with immunoglobulin A nephropathy (IgAN) is described in a 57-year-old man with a history of hypertension. Progressively worsening renal function was noted in the patient along with unexplained mild thrombocytosis. Pathological review of renal biopsy identified IgAN concurrently with newly diagnosed JAK2-mutated ET. The patient was started on aspirin therapy and closely monitored for his renal function. A literature review of the association of ET and renal disease revealed nine cases of ET associated with IgAN, focal segmental glomerulosclerosis, and fibrillary glomerulonephritis. Comparison of the pathological features of the renal biopsies within the cases noted mesangial proliferation as a common finding, which has been described to be potentiated by platelet-derived growth factor (PDGF). This commonality may represent a link between ET and glomerular disease which deserves further attention in future cases. Improved management of such cases depends on the recognition of the combined occurrence of ET and glomerular diseases and uncovering the shared pathogenesis between platelets and glomeruli.

Polycythemia vera and essential thrombocythemia: 2019 update on diagnosis, risk‐stratification and management

Disease Overview: Polycythemia vera (PV) and essential thrombocythemia (ET) are myeloproliferative neoplasms respectively characterized by erythrocytosis and thrombocytosis; other disease features include leukocytosis, splenomegaly, thrombosis, bleeding, microcirculatory symptoms, pruritus, and risk of leukemic or fibrotic transformation. Diagnosis: Bone marrow morphology remains the cornerstone of diagnosis. In addition, the presence of JAK2 mutation is expected in PV while approximately 90% of patients with ET express mutually exclusive JAK2, CALR, or myeloproliferative leukemia mutations. In ET, it is most important to exclude the possibility of prefibrotic myelofibrosis. Survival: Median survivals are 14 years for PV and 20 years for ET; the corresponding values for younger patients are 24 and 33 years. Certain mutations (mostly spliceosome) and abnormal karyotype might compromise survival in PV and ET. Life-expectancy in ET is inferior to the control population. Driver mutations have not been shown to affect survival in ET. Risk of thrombosis is higher in JAK2-mutated ET. Leukemic transformation rates at 10 years are estimated at <1% for ET and 3% for PV. Thrombosis Risk: In PV, 2 risk categories are considered: high (age > 60 years or thrombosis history present) and low (absence of both risk factors); in ET, 4 risk categories are considered: very low (age ≤ 60 years, no thrombosis history, JAK2 wild-type), low (same as very low but JAK2 mutation present), intermediate (age > 60 years, no thrombosis history, JAK2 wild-type) and high (thrombosis history present or age > 60 years with JAK2 mutation). Risk-Adapted Therapy: The main goal of therapy in both PV and ET is to prevent thrombohemorrhagic complications. All patients with PV require phlebotomy to keep hematocrit below 45% and once- or twice-daily aspirin (81 mg), in the absence of contraindications. Very low-risk ET might not require therapy while aspirin therapy is advised for low-risk disease. Cytoreductive therapy is recommended for high-risk ET and PV but it is not mandatory for intermediate-risk ET. First-line drug of choice for cytoreductive therapy, in both ET and PV, is hydroxyurea and second-line drugs of choice are interferon-α and busulfan. We do not recommend treatment with ruxolutinib in PV, unless in the presence of severe and protracted pruritus or marked splenomegaly that is not responding to the aforementioned drugs.

Mutational subtypes of JAK2 and CALR correlate with different clinical features in Japanese patients with myeloproliferative neoplasms.

The majority of patients with Philadelphia chromosome-negative myeloproliferative neoplasms (MPNs) harbor JAK2, CALR, or MPL mutations. We compared clinical manifestations of different subtypes of JAK2 and CALR mutations in Japanese patients with MPNs. Within our cohort, we diagnosed 166 patients as polycythemia vera (PV), 212 patients as essential thrombocythemia (ET), 23 patients as pre-primary myelofibrosis (PMF), 65 patients as overt PMF, and 27 patients as secondary myelofibrosis following the 2016 WHO criteria. Compared to patients with JAK2V617F-mutated PV, JAK2 exon 12-mutated PV patients were younger, showed lower white blood cell (WBC) counts, lower platelet counts, higher red blood cell counts, and higher frequency of thrombotic events. Compared to JAK2-mutated ET patients, CALR-mutated ET patients were younger, showed lower WBC counts, lower hemoglobin levels, higher platelet counts, and fewer thrombotic events. CALR type 1-like mutation was the dominant subtype in CALR-mutated overt PMF patients. Compared with JAK2V617F-mutated ET patients, JAK2V617F-mutated pre-PMF patients showed higher LDH levels, lower hemoglobin levels, higher JAK2V617F allele burden, and higher frequency of splenomegaly. In conclusion, Japanese patients with MPNs grouped by different mutation subtypes exhibit characteristics similar to those of their Western counterparts. In addition, ET and pre-PMF patients show different characteristics, even when restricted to JAK2V617F-mutated patients.

European LeukemiaNet study on the reproducibility of bone marrow features in masked polycythemia vera and differentiation from essential thrombocythemia.

The purpose of the study was to assess consensus and interobserver agreement among an international panel of six hematopathologists regarding characterization and reproducibility of bone marrow (BM) histologic features used to diagnose early stage myeloproliferative neoplasms, in particular differentiation of so-called masked/prodromal polycythemia vera (mPV) from JAK2-mutated essential thrombocythemia (ET). The six members of the hematopathology panel evaluated 98 BM specimens independently and in a blinded fashion without knowledge of clinical data. The specimens included 48 cases of mPV according to the originally published hemoglobin threshold values for this entity (male: 16.0-18.4 g/dL, female: 15.0-16.4 g/dL), 31 cases with overt PV according to the updated 2016 WHO criteria, and 19 control cases. The latter group included cases of JAK2-mutated ET, primary myelofibrosis, myelodysplastic syndrome, and various reactive conditions. Inter-rater agreement between the panelists was very high (overall agreement 92.6%, kappa 0.812), particularly with respect to separating mPV from ET. Virtually all cases of mPV were correctly classified as PV according to their BM morphology. In conclusion, a central blinded review of histology slides by six hematopathologists demonstrated that highly reproducible specific histological pattern characterize PV and confirmed the notion that there are no significant differences between mPV and overt PV in relation to BM morphology.

How We Treat Patients With Polycythemia Vera

How We Treat Patients With Polycythemia Vera

Rationale for revision and proposed changes of the WHO diagnostic criteria for polycythemia vera, essential thrombocythemia and primary myelofibrosis.

The 2001/2008 World Health Organization (WHO)-based diagnostic criteria for polycythemia vera (PV), essential thrombocythemia (ET) and primary myelofibrosis (PMF) were recently revised to accomodate new information on disease-specific mutations and underscore distinguishing morphologic features. In this context, it seems to be reasonable to compare first major diagnostic criteria of the former WHO classifications for myeloproliferative neoplasm (MPN) and then to focus on details that have been discussed and will be proposed for the upcoming revision of diagnostic guidelines. In PV, a characteristic bone marrow (BM) morphology was added as one of three major diagnostic criteria, which allowed lowering of the hemoglobin/hematocrit threshold for diagnosis, which is another major criterion, to 16.5 g/dl/49% in men and 16 g/dl/48% in women. The presence of a JAK2 mutation remains the third major diagnostic criterion in PV. Subnormal serum erythropoietin level is now the only minor criterion in PV and is used to capture JAK2-unmutated cases. In ET and PMF, mutations that are considered to confirm clonality and specific diagnosis now include CALR, in addition to JAK2 and MPL. Also in the 2015 discussed revision, overtly fibrotic PMF is clearly distinguished from early/prefibrotic PMF and each PMF variant now includes a separate list of diagnostic criteria. The main rationale for these changes was to enhance the distinction between so-called masked PV and JAK2-mutated ET and between ET and prefibrotic early PMF. The proposed changes also underscore the complementary role, as well as limitations of mutation analysis in morphologic diagnosis. On the other hand, discovery of new biological markers may probably be expected in the future to enhance discrimination of the different MPN subtypes in accordance with the histological BM patterns and corresponding clinical features.

New and treatment-relevant risk stratification for thrombosis in essential thrombocythemia and polycythemia vera.

New and treatment-relevant risk stratification for thrombosis in essential thrombocythemia and polycythemia vera.

JAK2 or CALR mutation status defines subtypes of essential thrombocythemia with substantially different clinical course and outcomes

AbstractPatients with essential thrombocythemia may carry JAK2 (V617F), an MPL substitution, or a calreticulin gene (CALR) mutation. We studied biologic and clinical features of essential thrombocythemia according to JAK2 or CALR mutation status and in relation to those of polycythemia vera. The mutant allele burden was lower in JAK2-mutated than in CALR-mutated essential thrombocythemia. Patients with JAK2 (V617F) were older, had a higher hemoglobin level and white blood cell count, and lower platelet count and serum erythropoietin than those with CALR mutation. Hematologic parameters of patients with JAK2-mutated essential thrombocythemia or polycythemia vera were related to the mutant allele burden. While no polycythemic transformation was observed in CALR-mutated patients, the cumulative risk was 29% at 15 years in those with JAK2-mutated essential thrombocythemia. There was no significant difference in myelofibrotic transformation between the 2 subtypes of essential thrombocythemia. Patients with JAK2-mutated essential thrombocythemia and those with polycythemia vera had a similar risk of thrombosis, which was twice that of patients with the CALR mutation. These observations are consistent with the notion that JAK2-mutated essential thrombocythemia and polycythemia vera represent different phenotypes of a single myeloproliferative neoplasm, whereas CALR-mutated essential thrombocythemia is a distinct disease entity.

Discriminating between essential thrombocythemia and masked polycythemia vera in JAK2 mutated patients

In patients not meeting the required hematocrit (HCT) or hemoglobin (Hb) thresholds according to BCSH and the WHO diagnostic criteria, the diagnosis of masked polycythemia vera (mPV) has been proposed. A comparison of HCT or Hb values with the expression of JAK2V617F, JAK2 exon 12, and CALR mutations in strictly WHO-defined 257 overt PV and 140 mPV (59 mPV according to BCSH) and 397 patients with essential thrombocythemia (ET) was performed. Hb and HCT thresholds of mPV patients were significantly higher than JAK2V617F ET (P < 0.0001). The best cut-off for Hb to discriminate JAK2-mutated ET from PV was 16.5 g/dL for males and 16.0 g/dL for females. For HCT, this was 49% in males and 48% in females. The proportion of patients correctly classified as ET or PV when regarding Hb or HCT levels was 95% in males and 93% in females and 94% in both males and females, respectively.

JAK2 (V617F)-Positive Essential Thrombocythemia and Polycythemia Vera Are Different Expressions Of a Genotypic/Phenotypic Continuum

BackgroundAbout 95% of patients with polycythemia vera (PV) and 60-70% of those with essential thrombocythemia (ET) carry the unique JAK2 (V617F) mutation. Previous observations suggest that JAK2 (V617F)-positive ET and PV form a biological continuum, in which the degree of erythrocytosis is determined by physiological and genetic factors. AimsIn this work, we studied the natural history of JAK2 (V617F)-positive ET and PV with the aim of establishing whether the two disorders indeed represent different phenotypic expression of a genotypic/phenotypic continuum. MethodsWe identified 1269 patients diagnosed with ET or PV at our Division between 1980 and 2012, for whom at least one DNA sample was available. The JAK2 (V617F) mutation was assessed using allele-specific quantitative PCR. As patients carrying JAK2 exon 12 or MPL mutations were excluded, the final study population included 1214 patients, 719 of whom with ET (463 JAK2 mutated, 256 JAK2 wild-type) and 495 with PV. ResultsI: presenting featuresThe clinical phenotype of ET patients at diagnosis differed according to JAK2 mutational status. JAK2 mutated ET presented with older age at diagnosis, higher hemoglobin (Hb) level and white blood cell (WBC) count, lower platelet (PLT) count and erythropoietin level compared to JAK2 wild-type ET (Wilcoxon rank-sum test: P<.001 in all comparisons).The median V617F allele burden was significantly lower in JAK2 mutated ET than in PV (18.4% vs 43.4%, P<.001). A mutant allele burden greater than 50% was observed in 2% of patients with JAK2 mutated ET and 41.5% of those with PV (Fisher exact test: P<.001). In both JAK2 mutated ET and PV, the mutant allele burden was directly related to WBC count and Hb level. ResultsII: PV evolutionEvolution to PV was observed in 53 JAK2 mutated ET patients (incidence 95% CI: 1.4-2.4 per 100 p-years) vs none of the 256 JAK2 wild-type ET (incidence 95% CI: 0-0.2 per 100 p-years), resulting in a significantly different occurrence. The median time to PV evolution was 54 months (range 3.5-220). The cumulative incidence of PV evolution in JAK2 mutated ET patients at 15 years was 28.8% (95% CI: 20.7-37.3; Figure 1). PV evolution was significantly associated with higher JAK2 allele burden at diagnosis (Cox regression HR=1.04, P<.001). [Display omitted] Based on the hypothesis that PV patients might have had a silent “pre-PV phase”, we did an ad hoc search for any complete blood count (CBC) collected before diagnosis. Among PV patients, 177 (36%) had a previous CBC, collected at a median time of 22 months (range 1-305) before PV diagnosis. A normal CBC was observed in 15% of patients; the remaining subjects showed thrombocytosis (≥450 x 109/L) and/or leukocytosis (≥10 x 109/L) and/or erythrocytosis. The median time to PV onset was significantly shorter in patients showing at least one CBC abnormality than in those with normal CBC (24 vs 48 months, P=.011). ResultsIII: clinical courseThe median follow-up was 5.1 years (range, 0-32 years). JAK2-mutated ET and PV did not differ in terms of cumulative incidence of thrombosis (25.3% vs 33.7% at 15 years, P=.35; Figure 2A) and had similar overall survival (OS) (90.3% vs 82.6% at 15 years, P=.29; Figure 2B). Conversely, JAK2 wild-type ET showed a better OS in comparison with both JAK2 mutated ET (P=.028) and PV (P=.004) and a lower incidence of thrombosis (12.7% at 15 years) than JAK2 mutated ET (P=.002) and PV (P<.001). [Display omitted] [Display omitted] A similar cumulative incidence of disease progression (leukemia and myelofibrosis) was observed in JAK2 mutated (11.7% at 15 years) and JAK2 wild-type ET (12.1% at 15 years), whereas a higher cumulative incidence was observed in PV (26% at 15 years; P=.011 and P=.007 when compared with JAK2 mutated ET and JAK2 wild-type ET respectively). ConclusionsThis study supports the hypothesis that JAK2 mutated ET and PV are different expressions of a genotypic/phenotypic continuum, in which the mutant allele burden contributes to determine the clinical phenotype. The risk of progression from JAK2 mutated ET to PV is about 2% per year.This work was supported by grant #1005 from Associazione Italiana per la Ricerca sul Cancro (AIRC) “Special Program Molecular Clinical Oncology 5x1000” to AGIMM (AIRC-Gruppo Italiano Malattie Mieloproliferative - http:www-progettoagimm.it). Disclosures:No relevant conflicts of interest to declare.