An increase in hemoglobin, platelets and white blood cells levels by iron chelation as single treatment in multitransfused patients with myelodysplastic syndromes: clinical evidences and possible biological mechanisms.

Iron chelation therapy can improve hematopoiesis in myelodysplastic syndromes. Only few studies showed hematologic improvement with deferoxamine, and the erythroid responses were correlated with good compliance to long-term treatment. Indeed, single-case reports and data from clinical trials testing the efficacy of deferasirox reported hematologic improvements with varying rates of response in different lineages. Overall, about 760 myelodysplastic syndrome (MDS) patients with iron overload receiving deferasirox were included in six different studies, and an increase in hemoglobin level was reported to range from 6 to 44.5%, an increase in platelet count from 13 to 61%, and in neutrophil count from 3 to 76%. In all the published studies, hematologic improvements were not related to serum ferritin or to non-total binding iron changes; indeed, other pathways were indicated as possible pathogenetic mechanisms, such as decreased NF-kB activity, modulation of mTOR signalling, and reduced reactive oxygen species. The aims of this review are to provide all available information relating clinical and hematologic changes after chelation therapy and to discuss potential mechanisms involved in such responses.

Therapeutic potential of MEK inhibition in acute myelogenous leukemia: rationale for "vertical" and "lateral" combination strategies.

In hematological malignancies, constitutive activation of the RAF/MEK/ERK pathway is frequently observed, conveys a poor prognosis, and constitutes a promising target for therapeutic intervention. Here, we investigated the molecular and functional effects of pharmacological MEK inhibition in cell line models of acute myeloid leukemia (AML) and freshly isolated primary AML samples. The small-molecule, ATP-non-competitive, MEK inhibitor PD0325901 markedly inhibited ERK phosphorylation and growth of several AML cell lines and approximately 70 % of primary AML samples. Growth inhibition was due to G(1)-phase arrest and induction of apoptosis. Transformation by constitutively active upstream pathway elements (HRAS, RAF-1, and MEK) rendered FDC-P1 cells exquisitely prone to PD0325901-induced apoptosis. Gene and protein expression profiling revealed a selective effect of PD0325901 on ERK phosphorylation and compensatory upregulation of the RAF/MEK and AKT/p70( S6K ) kinase modules, potentially mediating resistance to drug-induced growth inhibition. Consequently, in appropriate cellular contexts, both "vertical" (i.e., inhibition of RAF and MEK along the MAPK pathway) and "lateral" (i.e., simultaneous inhibition of the MEK/ERK and mTOR pathways) combination strategies may result in synergistic anti-leukemic effects. Overall, MEK inhibition exerts potent growth inhibitory and proapoptotic activity in preclinical models of AML, particularly in combination with other pathway inhibitors. Deeper understanding of the molecular mechanisms of action of MEK inhibitors will likely translate into more effective targeted strategies for the treatment of AML.