Treatment of acute promyelocytic leukaemia.

We review improvements achieved in the treatment of acute promyelocytic leukaemia (APL) over the last ten years. The combination of all- trans retinoic acid (ATRA) and conventional anthracycline-ARA-C chemotherapy (CT) has clearly demonstrated its superiority over CT alone (in terms of relapse and survival) in newly diagnosed APL. Combination treatment probably also reduces the incidence of initial failures, and complete remission (CR) rates greater than 90% are now regularly reported in large multicentre trials. Some randomized studies strongly suggest than prolonged maintenance treatment (for 1 or 2 years) with ATRA and low dose CT, and possibly very early introduction of anthracycline CT during induction treatment (i.e. not after ATRA) may reduce the incidence of relapse. With those treatments, the risk of relapse appears to be only 10-15%, although it remains greater in patients who initially have white blood cell counts (often associated with variant M(3)morphology, short bcr(3)isoform etc.) and patients with residual disease detectable by RT-PCR at the end of consolidation courses.ATRA syndrome remains the major side effect of ATRA treatment. It occurs in 10-15% of patients and is currently fatal in at least 10% of them. Rapid onset of CT and/or high dose steroids should improve its outcome.A sizeable proportion of APL patients who relapse after ATRA and CT can be durably salvaged by the same treatment followed by allogeneic or autologous stem cell transplantation, provided the transplant (in the autologous setting) is RT-PCR negative. Arsenic trioxide can induce CR in most APL patients refractory to ATRA and CT. It acts mainly by inducing apoptosis of APL cells. A place for arsenic trioxide earlier in the treatment of APL must currently be more precisely defined. Another issue in the treatment of APL is reducing the toxicity of first line treatment without increasing the relapse risk. Preliminary findings suggest that this could be achieved by consolidation CT using an anthracycline alone, without cytarabine.

Incidence, clinical features, and outcome of all trans-retinoic acid syndrome in 413 cases of newly diagnosed acute promyelocytic leukemia. The European APL Group.

All trans-retinoic acid (ATRA) syndrome is a life-threatening complication of uncertain pathogenesis that can occur during the treatment of acute promyelocytic leukemia (APL) by ATRA. Since its initial description, however, no large series of ATRA syndrome has been reported in detail. We analyzed cases of ATRA syndrome observed in an ongoing European trial of treatment of newly diagnosed APL. In this trial, patients 65 years of age or less with an initial white blood cell count (WBC) less than 5,000/microL were initially randomized between ATRA followed by chemotherapy (CT) (ATRA-->CT group) or ATRA with CT started on day 3; patients with WBC greater than 5,000/microL received ATRA and CT from day 1; patients aged 66 to 75 received ATRA-->CT. In patients with initial WBC less than 5, 000/microL and allocated to ATRA-->CT, CT was rapidly added if WBC was greater than 6,000, 10,000, 15,000/microL by days 5, 10, and 15 of ATRA treatment. A total of 64 (15%) of the 413 patients included in this trial experienced ATRA syndrome during induction treatment. Clinical signs developed after a median of 7 days (range, 0 to 35 days). In two of them, they were in fact present before the onset of ATRA. In 11 patients, they occurred upon recovery from the phase of aplasia due to the addition of CT. Respiratory distress (89% of the patients), fever (81%), pulmonary infiltrates (81%), weight gain (50%), pleural effusion (47%), renal failure (39%), pericardial effusion (19%), cardiac failure (17%), and hypotension (12%) were the main clinical signs, and 63 of the 64 patients had at least three of them. Thirteen patients required mechanical ventilation and two dialysis. A total of 60 patients received CT in addition to ATRA as per protocol or based on increasing WBC; 58 also received high dose dexamethasone (DXM); ATRA was stopped when clinical signs developed in 30 patients. A total of 55 patients (86%) who experienced ATRA syndrome achieved complete remission (CR), as compared with 94% of patients who had no ATRA syndrome (P = .07) and nine (14%) died of ATRA syndrome (5 cases), sepsis (2 cases), leukemic resistance (1 patient), and central nervous system (CNS) bleeding (1 patient). None of the patients who achieved CR and received ATRA for maintenance had ATRA syndrome recurrence. No significant predictive factors of ATRA syndrome, including pretreatment WBC, could be found. Kaplan Meier estimates of relapse, event-free survival (EFS), and survival at 2 years were 32% +/- 10%, 63% +/- 8%, and 68% +/- 7% in patients who had ATRA syndrome as compared with 15% +/- 3%, 77% +/- 2%, and 80% +/- 2% in patients who had no ATRA syndrome (P = .05, P = .003, and P = .03), respectively. In a stepwise Cox model that also included pretreatment prognostic variables, ATRA syndrome remained predictive for EFS and survival. In conclusion, in this multicenter trial where CT was rapidly added to ATRA in case of high or increasing WBC counts and DXM generally also used at the earliest clinical sign, the incidence of ATRA syndrome was 15%, but ATRA syndrome was responsible for death in only 1.2% of the total number of patients treated. However, occurrence of ATRA syndrome was associated with lower EFS and survival.

Retroviral transfer and long-term expression of the adrenoleukodystrophy gene in human CD34+ cells.

Adrenoleukodystrophy (ALD) is a demyelinating disease of the central nervous system that results from a genetic deficiency of ALDP, an ABC protein involved in the transport of very long-chain fatty acids (VLCFAs). The cloning of the ALD gene and the positive effects of allogeneic bone marrow transplantation support the feasibility of a gene therapy approach. We report the retroviral transfer of the ALD cDNA to peripheral blood and bone marrow CD34+ cells from control donors and ALD patients. Prestimulation of these cells with cytokines, followed by infection with the M48-ALD retroviral vector, resulted in 20% transduction efficiency (4-40%) and expression of the vector-encoded ALDP in 20% of CD34+ cells (7.3-50%). Long-term culture (LTC) of transduced CD34+ cells from two ALD patients showed efficient transduction (24-28%) and stable expression (25-32%) of ALDP in derived clonogenic progenitors at 3 weeks of culture. The expression of ALDP in CFU cells derived from 5 and 6 weeks of LTC confirmed the effective transduction of LTC-initiating cells. Expression of ALDP was observed in CD68+ CFU-derived cells, suggesting that monocyte-macrophages, the target bone marrow cells in ALD, were produced from transduced progenitor cells. VL-CFA content was corrected in LTC and CFU-derived cells in proportion to the percentage of transduced cells, indicating that the vector-encoded ALDP was functional. Although not efficient yet to allow a clinical perspective, these results demonstrate the feasibility of ALD gene transfer into CD34+ cells of ALD patients.

Midkine (MK), a retinoic acid (RA)-inducible gene product, produced in E. coli acts on neuronal and HL60 leukemia cells.

We have shown previously that (i) retinoic acid (RA), an anti-neoplastic agent, activates the midkine (MK) gene in mammalian embryonic carcinoma cells, and that (ii) the MK of 118 amino acids, purified from L cells, induces neurite outgrowth of mammalian embryonic brain cells. In this paper, we describe an unconventional strategy for the purification of a fully active MK from E. coli with a high yield. The MK was overproduced in E. coli as a glutathione S-transferase (GST) fusion protein. The MK fusion protein extracted from the bacterial inclusion bodies with guanidine-HCl was renatured, refolded slowly and cleaved by thrombin at the site where the GST links to the MK. The purified free MK, like RA, induced neurite outgrowth from central neurons of the mouse spinal cord, and suppressed the growth of human HL60 leukemia cells in vitro. Unlike RA, however, the MK did not induce granulocytic differentiation of HL60 cells. Furthermore, the MK supported the survival of an NGF-insensitive sensory neuron subpopulation(s) from chicken embryo dorsal root ganglion. Thus, the actions of the MK and leukemia inhibitory factor (LIF) are surprisingly similar. There is no sequence similarity between MK and LIF, however, and unlike MK, LIF production does not appear to be RA-inducible.