Thrombopoietic factors in chronic bone marrow failure states: the platelet problem revisited.

Thrombocytopenia is a serious clinical problem in several different clinical settings. In chronic bone marrow failure states, which include aplastic anemia, myelodysplastic syndrome, and graft failure, the prolonged nature of thrombocytopenia often leads to alloimunization after repeated platelet transfusions, the consequence of which is a platelet-refractory state and enhanced risk of bleeding. Despite the introduction of several thrombopoietic factors into clinical trials, an effective way to alleviate thrombocytopenia has been elusive, and the problem in chronic bone marrow failure states has remained poorly addressed by clinical investigations. Even so, several studies by our group and others suggest that a subset of patients suffering from chronic bone marrow failure can respond to appropriate growth factor therapy. The temporal pace of response appears, however, to be much slower than that observed after administering growth factors which act on neutrophils. On the other hand, durable responses can be secured in some patients given thrombopoietic factors for long periods of time. Herein, we provide an overview of the clinical research investigations of thrombopoietic factors in chronic bone marrow failure, and the emerging insights these studies provide for understanding the process of thrombopoiesis and its therapy in this setting.     

LIF: not just a leukemia inhibitory factor

Increasingly it seems that many cytokines are pleiotropic, and individual molecules may have critical roles in several different organ systems. LIF exemplifies this phenomenon: it influences embryogenesis, bone and lipid metabolism, and hematopoietic and nervous system function. Many of LIF's effects are reminiscent of those of IL-1, TNF, and TGF-beta. Further, even within a single system, LIF can display totally different effects, i.e. induction of differentiation of one leukemic cell line vs. stimulation of proliferation of another. The corollary to these observations is that there appears to be many parallels in developmental systems. For instance, in the case of neuronal "lineage commitment," the events that relate to migration of neural crest cells along various pathways and their ultimate arrest in different locales demonstrate sufficient analogies to hematopoietic lineage commitment phenomena that, in a provocative review, Anderson coined the term "neuropoiesis". This type of analogy becomes even more intriguing when one realizes that some of the same molecules are regulating neuronal and hematopoietic "lineage" proliferation and differentiation. In this respect, several interleukins in addition to LIF are important in neuronal development, and nerve growth factor turns out to also be a hematopoietic regulatory molecule. Similar parallels are enacted in other organ systems as well. The mediation of identical effects by distinct cytokines bound to unique receptors could conceivably be explained by receptor transmodulation or by overlapping signaling sequences. It is nevertheless also unclear how a single cytokine attached to a single receptor can accomplish varied and opposing effects, although divergent intracellular signaling mechanisms could account for some of these phenomena. Yet another enigma relates to how cells from one system can be properly influenced by a pleiotropic molecule such as LIF without significant "cross-effects" on other potentially responsive systems. Cytokine production that is restricted to certain developmental stages, or very localized distribution and spheres of influence within a microenvironment, could be explanatory. The findings of Rathjan and colleagues, i.e. that LIF exists as both a diffusible molecule and as a molecule incorporated into the extracellular matrix, is of special interest in relation to the above questions. Indeed, the distinctions between the roles of diffusible and immobilized signaling molecules could be crucial to the multiplicity of LIF's actions. Diffusible regulatory factors allow communication between spatially separated cells. Cellular responsiveness to such factors is dictated by the presence of appropriate receptors and postreceptor machinery.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phase I dose-escalation trial of the oral AKT inhibitor uprosertib in combination with the oral MEK1/MEK2 inhibitor trametinib in patients with solid tumors

This study aimed to determine the safety, tolerability, and recommended phase II doses of trametinib plus uprosertib (GSK2141795) in patients with solid tumors likely to be sensitive to MEK and/or AKT inhibition. This was a phase I, open-label, dose-escalation, and dose-expansion study in patients with triple-negative breast cancer or BRAF-wild type advanced melanoma. The primary outcome of the expansion study was investigator-assessed response. Among 126 enrolled patients, 63 received continuous oral daily dosing of trametinib and uprosertib, 29 received various alternative dosing schedules, and 34 were enrolled into expansion cohorts. Doses tested in the expansion cohort were trametinib 1.5 mg once daily (QD) + uprosertib 50 mg QD. Adverse events (AEs) were consistent with those reported in monotherapy studies but occurred at lower doses and with greater severity. Diarrhea was the most common dose-limiting toxicity; diarrhea and rash were particularly difficult to tolerate. Overall, 59% and 6% of patients reported AEs with a maximum severity of grade 3 and 4, respectively. Poor tolerability prevented adequate delivery of uprosertib with trametinib at a concentration predicted to have clinical activity. The study was terminated early based on futility in the continuous-dosing expansion cohorts and a lack of pharmacological or therapeutic advantage with intermittent dosing. The objective response rate was < 5% (1 complete response, 5 partial responses). Continuous and intermittent dosing of trametinib in combination with uprosertib was not tolerated, and minimal clinical activity was observed in all schedules tested.     

Recombinant interferon gamma in hairy cell leukemia, multiple myeloma, and Waldenstrom's macroglobulinemia

Fifteen patients with multiple myeloma, five with hairy cell leukemia, and five with Waldenstrom's macroglobulinemia were treated with recombinant interferon gamma (rINF-gamma) to determine the antitumor activity of this agent. The rIFN-gamma was administered by daily intramuscular injection at doses ranging from 0.125 to 0.5 mg/m2. No responses were observed in patients with multiple myeloma, although in one patient the disease has remained stable for over 16 months. Minimal improvement in some hematologic indexes were observed in three of five patients with hairy cell leukemia. One partial remission and one minor response were documented in two of the five patients with Waldenstrom's macroglobulinemia. In five patients, an increase in normal serum immunoglobulins was observed. These results suggest that there is only minimal activity of rIFN-gamma as a single agent in neoplasms of B-cell origin.     

Expression of c-abl in Philadelphia-positive acute myelogenous leukemia

The identical cytogenetic marker, t(9;22)(q34;q11) (Philadelphia [Ph] translocation), is found in approximately 90%, 20%, and 2% of adult patients with chronic myelogenous leukemia (CML), acute lymphoblastic leukemia (ALL), and acute myelogenous leukemia (AML), respectively. In CML, the molecular events resulting from the Ph translocation include a break within the bcr locus on chromosome 22, transfer of the c-abl protooncogene from chromosome 9 to 22, and formation of an aberrant 210- kD bcr-abl fusion protein (p210bcr-abl). Recently, the absence of bcr rearrangement and expression of a distinct aberrant 190-kd abl protein (p190c-abl) has been described in Ph-positive ALL, with the suggestion that the two abl variants may be pathogenetically associated with myeloid v lymphoid leukemogenesis. Here we report that the genomic configuration and translation product of Ph-positive AML can be similar to that of Ph-positive ALL: the break at 22q11 may occur outside the 5.8 kb bcr region and result in expression of a 190-kD abl protein lacking these bcr sequences. Phosphokinase enzymatic activity, a fundamental property of p210bcr-abl, was also associated with AML- derived p190c-abl. Our current observations indicate that p190c-abl can be found in cells of lymphoid or myeloid lineage and is therefore unlikely to play a specific role in the development of lymphoid leukemias. Formation of p190c-abl instead of p210bcr-abl appears to be a characteristic of the acute rather than the chronic Ph-positive leukemic state.