JAK2 is a tyrosine kinase gene that plays an essential role in the development of normal haematopoiesis. Hyperactivation of JAK2 occurs in myeloproliferative neoplasms by different mechanisms. As a consequence, JAK2 inhibitors have been designed to suppress the cytokine signalling cascade caused by the constitutive activation of JAK2. In clinical trials, JAK2 inhibitors are efficient in decreasing spleen size, controlling clinical symptoms, and improving quality of life in patients with myeloproliferative neoplasms. However, JAK2 inhibitors are unable to target uncommitted hematopoietic progenitors responsible of the initiation of the myeloproliferative disease. It is expected that, in order to cure the myeloproliferative disease, JAK2 inhibitors should be combined with other drugs to target simultaneously different pathways and to target the initiator hematopoietic cell population in myeloproliferative disorders. Taking advantage of the inhibition of the cytokine cascade of JAK2 inhibitors, these compounds are going to be used not only to treat patients with hematological neoplasms but may also be beneficial to treat patients with rheumatoid arthritis or other inflammatory diseases.
1. Introduction
Myeloproliferative neoplasms (MPNs) are clonal disorders up to now characterized by the autonomous proliferation of committed hematopoietic progenitors secondary to an aberrant activation of tyrosine kinase (TK) signalling pathways in combination with an exaggerated response to hematopoietic cytokines and growth factors [1, 2]. Constitutive activation of TKs is a consistent molecular signature in cell proliferation. Examples of Constitutive activation of TKs are seeing in solid tumours [3, 4], rheumatoid arthritis [5], and hematopoietic malignancies [6]. Known mechanisms of TK activation may result from acquired heterozygote of homozygote point mutations [7, 8], internal tandem duplications [9], and chromosomal translocations [10, 11]. The knowledge of the molecular mechanism involved in the pathogenesis of chronic myeloid leukemia (CML) [12] has allowed to elucidate the molecular dissection of chronic proliferation in MPN. Using CML as paradigm of constitutive activation of TK in chronic myeloproliferation, James et al. sequenced the coding exons and intron-exon junctions of JAK2 in 3 polycythemia vera (PV) patients and 2 controls. In 2 of these patients a G-to-T mutation at nucleotide 1849 in exon 12 was found, leading to a substitution of valine to phenylalanine at position 617 (V617F). This mutation was not a polymorphism, but a recurrent acquired mutation that was found in granulocytes, erythroblasts, and platelets of 40 out of 45 PV patients but not in any controls or patients with secondary erythrocytosis [13]. JAK2V617F was also found in other BCR-ABL negative MPN [14]. JAK2V617F occurs in the pseudokinase domain of the JAK2 gene. The mutated pseudokinase domain is not able to negatively regulate the kinase domain of JAK2, resulting in an autonomous activation of the JAK2 kinase domain with subsequently persistent phosphorylation of STAT and MAPK proteins [15, 16] and hyperstimulation of the cytokine signalling pathway [17]. As a consequence, cells expressing the JAK2V617F mutation are hypersensitive to hematopoietic cytokine stimulation, resulting in an abnormal erythroid-, myeloid-, and thromboproliferation. Moreover, JAK2-deficient mice do not survive because of absence of erythropoiesis. Myeloid progenitors of these mice fail to respond to EPO, GM-CSF, and thrombopoietin stimulation [18]. These experiments demonstrate that JAK2 plays an essential role in the development of normal hematopoiesis.
Not all patients with “classical” MPN carry the JAK2V617F mutation. This mutation is present in almost all PV patients, but only in half of the patients with essential thrombocythemia (ET) and primary myelofibrosis (PMF), suggesting that there are alternative routes of JAK-cytokine signalling activation [14]. In the most prevalent BCR-ABL1 negative MPN (PV, ET, and PMF), up to now it is known that JAK2 activation may also occur by JAK2 mutations in exon 12 [19], by mutations in the inhibitory adaptor protein LNK [20], or by a TEL-JAK2 chromosomal translocation that induces erythropoietin-independent erythroid differentiation and myelofibrosis [21]. Other mutations described in MPN but also in other haematological malignancies are mutations in the thrombopoietin receptor at codon 515 (MPL) [22], the isocitrate dehydrogenase family genes (IDH), the additional sex combs like 1 gene (ASXL1), the casitas B-lineage lymphoma proto-oncogene (CBL), the TET oncogene family member 2 (TET2), and the Ikaros family zinc finger 1 gene (IKZF1) [23]. These mutations promote hematopoietic proliferation via other pathways than JAK-cytokine signalling activation and they have been detected more frequently in MPN other than PV, ET of PMF, myelodysplastic syndromes, secondary acute myeloid leukemia, and blast-transformation phase of MPN.
There is a relationship between the underlying genetic mechanism of the MPN and the response to different treatments. For example, 40–50% of the patients with primary PMF and ET who carried JAK2V617F mutation had decreases in proportion of JAK2-mutated DNA [24]. About 20% of the PMF and ET patients who carried MPL mutations had no decreases in proportion of MPL-mutated DNA when treated with JAK2 inhibitors but they did have it when treated with biological response modifiers (pegylated-interferon alpha 2a, lenalidomide, and prednisone) [24].
New biological properties of JAK2 are currently being investigated. Recently, it has been demonstrated that JAK2 is not only localised in the cytoplasm of hematopoietic cells where JAK2 plays a role in the cytokine signalling pathway, but also in the nucleus of hematopoietic cells [25]. In the nucleus, a hyperactive JAK2 induces phosphorylation of the histone H3 at tyrosine residue 41 (H3Y41), releasing the transcriptional repressor heterochromatin protein 1alfa (HP1a) from chromatin and resulting in an activation of transcription of genes repressed by HP1a, as the oncogene LMO2. LMO2 might play a role in the pathogenicity of MPN. It is remarkable that H3Y41 phosphorylation requires a hyperactive JAK2, implying that the activation of different pathways with different JAK2 effectors and different target genes is involved in the pathogenesis of MPN.
In the era of JAK2 inhibitors, this finding opens new possibilities for combined therapeutic targets (JAK2 inhibitors and histone posttranslational modificators) that may benefit patients with MPN [26].
2. Current Therapies for BCR-ABL1 Negative MPN (PV, ET, and PMF) Based on JAK2 Inhibitors and Their Combinations
Hyper-activation of JAK2 is a critical step in the pathogenesis of BCR-ABL1 negative, classical MPN.
Autonomous activation of the JAK2 kinase domain with subsequently persisting phosphorylation of STAT and MAPK proteins occurs in patients with and without JAK2V617F mutations. JAK2 inhibitors have been designed to suppress the cytokine signalling induced by a hyperactive cytoplasmatic JAK2 gene. JAK2 inhibitors compete for the ATP-binding pocket of the tyrosine kinase domain of JAK2 [27]. Because JAK2V617F mutation is localized outside the ATP-binding site, JAK2 inhibitors do not discriminate between JAK2 and JAK2-mutated genes [28]. In consequence, JAK2 inhibitors can be used in patients with MPN independently of the JAK2 mutation status.
Nowadays, several JAK2 inhibitors are tested in clinical trials in Europe and USA (INCB018424, TG101348, CYT387, CEP-701, AZD1480, SB1518, and XL019) and others (NCB016562, NVP-BSK805, and R723) are in preclinical development.
INCB018424 known as Ruxolitinib is a potent and selective JAK1 and JAK2 inhibitor. It has been used in patients with PMF, where INCB018424 downregulates proinflammatory cytokines through the inhibition of JAK1 and suppresses the phosphorylated signal of STAT3 through the inhibition of JAK2, independently of the presence of JAK2V617F mutation [29].
In animal models of JAK2V617F mutation MPN, oral INCB018424 markedly reduced splenomegaly and circulating levels of inflammatory cytokines and preferentially eliminated neoplastic cells, resulting in significantly prolonged survival without myelosuppressive or immunosuppressive effects [30].
In patients with PMF treated with INCB018424, a significant reduction of constitutional symptoms and more than 50% reduction of splenomegaly occurred. Clinical benefits were associated with a marked decrease of levels of circulating inflammatory cytokines, although the load of JAK2V617F was marginally reduced [29]. Myelosuppression grade 3 or 4 was observed in less than 10% of the patients.
TG101348, also known as SAR302503, is a selective small-molecule JAK2 antagonist that inhibits primary hematopoietic cells derived from patients with MPN and with JAK2V617F, MPLW515K, JAK2 exon 12 mutations as well as mutation negative patients [31]. In animal models of JAK2V617F positive MPN, TG101348 reduced erythrocyte and leukocyte counts, the extramedullary hematopoiesis, and myelofibrosis without toxicities [31, 32]. Biologically, TG101348 reduced the JAK2V617F disease burden, and it was demonstrated a suppression of endogenous erythroid colony formation and inhibition of phosphorylated STAT5 [31]. In patients with myelofibrosis, TG101348 induced a reduction of the spleen size according to the criteria of International Working Group for Myelofibrosis Research and Treatment (IWG-MRT) [33] and a normalization of blood counts after 6 and 12 cycles [34]. A significant decrease in JAK2V617F allele burden was observed at 6 months in mutation-positive patients with a consistent decrease at 12 months [34].
CYT387 is an ATP-competitive potent JAK1, JAK2, and tyrosine kinase 2 (TYK2) inhibitor, at nanomolar concentrations, more selective against JAK2 than against other tyrosine kinases in comparison with other JAK2 inhibitors [35]. Its effect has been analyzed in cell lines harboring mutated JAK2 alleles, showing an inhibition of growth of erythroid colonies and erythroleukemia cells and inhibition of STAT5 phosphorylation.
In a murine MPN model, CYT387 normalized erythrocytes, leukocytes, spleen size, and restored physiologic levels of inflammatory cytokines. Biologically, there was a reduction of the JAK2V617F allele burden. However, after cessing therapy, JAK2V617F positive cells persisted and MPN relapsed [35].
CEP-701 known as Lestaurtinib is an Fms-like tyrosine kinase 3 (FLT3) inhibitor in current use on acute myeloid leukemia clinical trials and a JAK2 kinase inhibitor which suppresses phosphorylation induced by JAK2 tyrosine kinase. In patients with PV, CEP-701 inhibited growth of expanded erythroid cells [36]. In 22 patients with PMF who carried out the JAK2V617F mutation, CEP-701 induced a modest clinical recovery with mainly improvement of the spleen size. Biologically there was no improvement in bone marrow fibrosis or JAK2V617F allele burden [37]. Mainly toxicities have a high incidence of any grade of gastrointestinal toxicity in 9–72% of the patients and haematological toxicity grade 3-4 in 14–23% of the patients [37].
JAK2 inhibitors can be compared with BCR-ABL1 inhibitors, since both sort of drugs are TK inhibitors. Nevertheless, whereas BCR-ABL1 inhibitors are directed against an aberrant fusion gene [38], JAK2 inhibitors are directed against a gene which is present in normal cells and have an important role in the development of normal hematopoiesis. This means that adverse events are induced with JAK2 inhibitors at doses to be able to control the myeloproliferative phenotype, inducing often grade 3-4 hematological toxicity as seen in clinical trials, limiting the clinical efficiency of JAK2 inhibitors. Different studies describe the incidence of reversible grade 3 or 4 hematological toxicity between 3–35% depending on the inhibitor specificity [34, 37, 39]. Other common adverse events are gastrointestinal symptoms, probably related to the inhibition of other tyrosine kinases. The incidence of nausea, vomiting, and diarrhoea varies between 5–70% depending on the compound [34, 37, 39].
Up to now it is known that JAK2 is a member of a family of tyrosine kinases present in the cytoplasm of hematopoietic cells. Recently, it has been demonstrated that JAK2 is also present in the nucleus of hematopoietic cells where it indirectly activates the expression of oncogenes as LMO2 [25]. It is not yet well known whether JAK2 inhibitors have a role in the inhibition of the JAK2 nuclear function. In the next years, the increasing clinical and biological experience with JAK2 inhibitors will clarify their role.
Although imatinib treatment in CML cannot directly be compared with JAK2 inhibition in MPN, it can be used as a model of clinical experience with TK inhibitors. Therefore, we can speculate about what it is going to happen with the use of JAK2 inhibitors in the clinical practice. One might expect the drug resistance to JAK2 inhibitors by acquisition of mutations in the ATP-binding pocket of the TK domain of JAK2 and/or via the amplification of JAK2. We can also expect that JAK2 inhibitors are efficient to alleviate the clinical symptoms of patients with MPN, when used as monotherapy, but inefficient to cure the disease as happened with imatinib [40]. Clinical trials using JAK2 inhibitors for patients with myelofibrosis have demonstrated the effectiveness of these drugs to reduce clinical symptoms splenomegaly and to improve quality of life. However, in these trials, JAK2 burden was slightly reduced, indicating that JAK2 inhibitors are efficient to block the cytokine pathway responsible of the clinical symptoms in patients with MPN, but are not enough efficient to block the main molecular mechanism that originates the disease. Recently, Mullally et al. [41], using a JAK2V617F knock-in mouse MPN model, have shown that JAK2 inhibitors are able to control the hyperproliferation of committed hematopoietic progenitors in MPN, but are unable to eliminate the cell population from which the initiator clone arises. This cell population has been identified as noncommitted hematopoietic progenitors JAK2V617F+, Lin−, Sca+ c-kit+ (LSK positive). JAK2 inhibitors may have to be used in combination with drugs which target the LSK positive noncommitted population to be able to cure MPN.
Given the fact that JAK2 inhibitors induce myelosuppression but cannot cure MPN, combinations with other compounds that might have therapeutic synergy with JAK2 inhibitors seem to be mandatory. In this sense, interferon-alpha therapy is a good option to be associated to JAK2 inhibitors, due to its multiple effects on the regulation of immune modulatory cells, the expression of apoptotic genes, inhibition of angiogenesis, suppression of the proliferation of hematopoietic progenitor cells, and promoting the cycling of hematopoietic stem cells [42, 43]. It is thought that interferon-alpha can also inhibit the cytokine signalling coming from bone marrow stromal cells to support proliferation and survival of malignant cells in MPN. Recently, Manshouri et al. have demonstrated that humoral factors secreted by the bone marrow stromal cells protect malignant cells carrying JAK2V617F from the therapeutic effect of the JAk2 inhibitors [44]. Thus, combination of JAK2 inhibitors and interferon alpha could be a more efficient therapeutic regimen to treat MPN patients than only JAK2 inhibitors.
Other immunomodulatory drugs are also been tested in MPN patients, mainly in those with myelofibrosis. Thalidomide and lenalidomide with or without prednisone have shown efficacy to inhibit the increased cytokine production in these patients, decreasing the spleen size, myelofibrosis, and inhibiting angiogenesis [45]. Pomalidomide, another analogue, is currently being evaluated with or without prednisone in large clinical trials to treat patients with myelofibrosis [46]. These immunomodulatory drugs are candidates to be associated to JAK2 inhibitors as targeting therapy in patients with MPN.
Classical therapies, as hydroxycarbamide, are also effective to treat patients with MPN, not only as cytoreduction therapy but also as therapy to decrease the JAK2V617F load. Recently, Besses et al. have shown that hydroxycarbamide can reduce the JAK2 mutant load to more than 50% in untreated patients diagnosed with PV and TE [47]. This effect has synergy with the therapeutic effect of JAK2 inhibitors, making hydroxycarbamide a candidate therapy to be combined with JAK2 inhibitors.
JAK2 inhibitors are effective to alleviate clinical symptoms in patients with BCR-ABL negative MPN. Combination with other therapies which show synergy and other biological properties than JAK2 inhibitors is promising as the most effective therapy in these disorders (Table 1).
Current therapies for BCR-ABL1 negative MPN patients to be combined with JAK2 inhibitors.
Drug
Target
Results
JAK2V617F load
Reference
JAK2 inhibitors
INCB018424 Ruxolitinib
JAK2, JAK1
>50% reduction in splenomegaly and constitutional symptoms
JAK2V617F load marginally reduced
Verstovsek et al. [29]
TG101348 or SAR302503
JAK2, FLT3
Reduction in splenomegaly
JAK2V617F load significantly reduced
Pardanani et al. [34]
CYT387
JAK2, JAK1, TYK2
In a murine model, normalized erythrocytes, leukocytes, spleen size, and levels of inflammatory cytokines
JAK2V617F load reduced
Tyner et al. [35]
CEP-701 Lestaurtinib
JAK2, FLT3
Reduction in splenomegaly
JAK2V617F load no reduced
Hexner et al. [36] Santos et al. [37]
Immunomodulators
Interferon-alpha
Stromal cells
Inhibit cytokine signalling, proliferation and angiogenesis
Unknown
Kiladjian et al. [43]
Thalidomide
Stromal cells
Inhibition of angiogenesis
Unknown
Jabbour et al. [45]
Lenalidomide
Stromal cells
Inhibition of angiogenesis
Unknown
Jabbour et al. [45]
Pomalidomide
Stromal cells
Inhibition of angiogenesis
Unknown
Begna et al. [46]
Other
Hydroxycarbamide
JAK2 mutant burden
Inhibition of proliferation
JAK2V617F load significantly reduced
Besses et al. [47]
Histone post-translationa modificators
JAK2 nuclear
Depletion of JAK2V617F autophosphorylation, apoptosis in vitro
Unknown
Wang et al. [26]
3. Final Remarks
JAK2 is a tyrosine kinase gene which plays an essential role in the development of normal haematopoiesis and in the cytokine signalling pathway involving STAT3 and STAT5 proteins. Hyperactivation of JAK2 occurs in MPN by different genetic mechanisms. JAK2 inhibitors have been designed to suppress the cytokine cascade initiated by the activation of JAK2, independently of the underlying genetic mechanism. In phase II/III of clinical trials, JAK2 inhibitors are efficient to control clinical symptoms and to improve quality of life. Recently, it has been demonstrated that JAK2 can also be located in the nucleus of cells, where it plays a role in the transcriptional control of genes regulated by HP1a. Whether JAK2 inhibitors may have a role in the suppression of the nuclear role of JAK2 or not is at the moment unknown, but it opens new insights for the combined use of epigenetic therapy with JAK2 inhibitors for the treatment of MPN.
Recently, it has also been demonstrated that JAK2 inhibitors are unable to target uncommitted hematopoietic progenitors responsible of the initiation of the myeloproliferative disease. It is expected that, in order to cure the MPN disease, JAK2 inhibitors should be combined with other drugs to target simultaneously different pathways and to target the initiator hematopoietic LSK positive cell population in MPN.
Taking advantage of the inhibition of the cytokine cascade of JAK2 inhibitors, these compounds are going to be used not only to treat patients with MPN, but also patients with autoimmune diseases as rheumatoid arthritis, Crohn’s disease, or Colitis ulcerosa.
Authors’ Contribution
M. Bellido and P. Boekhorst conceived the study, P. Boekhorst reviewed the paper and contributed to the final draft. M. Bellido declares that there are no competing financial interests in relation to this work. P. Boekhorst is a member of an advisory board of Novartis.
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