Multidrug Resistance (MDR) Gene Expression in Acute Non Lymphoblastic Leukemia: Sequential Analysis

Effect of amifostine on the cytotoxicity of daunorubicin and daunoxome in tumor and normal cells

Anthracyclines are powerful cytotoxic agents, used as first-line treatment of leukemias and many other tumors, but host-tissue toxicity is their main dose-limiting factor. However, their therapeutic effects depend not only on the toxicity, hence on the dose, but also on drug resistance. Among the mechanisms that can account for cell sensitivity to anthracyclines, there is an overexpression of drug transport proteins, like the transmembrane P-glycoprotein (PGP), the multidrug- resistance-related protein (MRP) and the lung-resistance-related protein (LRP). Attempts to reduce the toxicity of chemotherapeutic agents without affecting their efficacy have been made using liposomal anthracyclines or cytoprotective agents, as Amifostine. The aim of this study was to evaluate and compare the toxic effects of Daunorubicin, in normal or liposomal formulation, used in combination with WR1065, the active metabolite of Amifostine, against normal and tumor cells. In conclusion these data show that the preincubation with WR-1065 does not inhibit the drug toxic effect on blast cells and on tumor cell lines, independently by their multidrug resistance phenotype, but has a cytoprotective effect on stem cells causing a drug cytotoxicity reduction of 10-20%. This advantage is even higher using the liposomal formulation of DNR. Therefore, Amifostine can offer a chance of protecting normal cells from the toxicity of anthracyclines, in normal or liposomal formulation. The combination of liposomal anthracyclines with Amifostine can confer further advantages in management of leukemic patients, especially the elderly where treatment toxicity is a main problem. These patients may be candidates for alternative therapeutic strategies and the combination of DNX and Amifostine is an attractive treatment for these cases where a low nonhematological toxicity is required.

Quinine improves results of intensive chemotherapy (IC) in myelodysplastic syndromes (MDS) expressing P-glycoprotein (PGP). Updated results of a randomized study. Groupe Français des Myélodysplasies (GFM) and Groupe GOELAMS

We designed a randomized trial of IC with or without quinine, an agent capable of reverting the multidrug resistance (mdr) phenotype, in patients aged < or = 65 years with high risk MDS. Patients were randomized to receive Mitoxantrone 12 mg/m2/d d2-5 + AraC 1 g/m2/12 h d1-5, with (Q+) or without (Q-) quinine (30 mg/kg/day). 131 patients were included. PGP expression analysis was successfully made in 91 patients and 42 patients (46%) had positive PGP expression. In PGP positive cases, 13 of the 25 (52%) patients who received quinine achieved CR, as compared to 3 of the 17 (18%) patients treated with chemotherapy alone (p = 0.02). In PGP negative cases, the CR rate was 35% and 49%, respectively in patients who received quinine or chemotherapy alone (difference not significant). In the 42 PGP positive patients, median Kaplan-Meier (KM) survival was 13 months in patients allocated to the quinine group, and 8 months in patients treated with chemotherapy alone (p = 0.01). In PGP negative patients, median KM survival was 14 months in patients allocated to the quinine group, and 14 months in patients treated with chemotherapy alone. Side effects of quinine mainly included vertigo and tinnitus that generally disappeared with dose reduction. Mucositis was significantly more frequently observed in the quinine group. No life threatening cardiac toxicity was observed. In conclusion, results of this randomized study show that quinine increases the CR rate and survival in PGP positive MDS cases treated with IC. The fact that quinine had no effect on the response rate and survival of PGP negative MDS suggests a specific effect on PGP mediated drug resistance rather than, for instance, a simple effect on the metabolism of Mitoxantrone and/or AraC.

Quinine improves the results of intensive chemotherapy in myelodysplastic syndromes expressing P glycoprotein: results of a randomized study

Intensive chemotherapy produces a lower complete remission (CR) rate in the myelodysplastic syndromes (MDS) than in de novo acute myeloid leukaemia (AML), possibly due in part to a higher incidence of P glycoprotein (PGP) expression in MDS blast cells. We designed a randomized trial of intensive chemotherapy with or without quinine, an agent capable of reverting the multidrug resistance (mdr) phenotype, in patients aged < or = 65 years with high-risk MDS. Patients were randomized to receive mitoxantrone 12 mg/m2/d days 2-5 + AraC 1 g/m2/12 h days 1-5, with (Q+) or without (Q-) quinine (30 mg/kg/d). 131 patients were included. PGP expression analysis was successful in 91 patients. In the 42 PGP-positive cases, 13/25 (52%) patients in the Q+ group achieved CR, compared to 3/17 (18%) patients in the Q- group (P = 0.02) and median Kaplan-Meier survival was 13 months in the Q+ group, and 8 months in the Q- group (P = 0.01). No life-threatening toxicity was observed with quinine. In conclusion, the results of this randomized study show that quinine increases the CR rate and survival in PGP-positive MDS cases treated with intensive chemotherapy.

Repeated cycles of G-CSF-combined postremission chemotherapy for acute myeloid leukemia in a first complete remission: a pilot study

The cure rate of acute myeloid leukemia might increase if G-CSF were given concurrently with repeated postremission chemotherapy. However, this therapy might cause severe complications, including depletion of normal hematopoietic progenitors as a long-term toxicity. Thus, we conducted a pilot study of this strategy. Twenty-six acute myeloid leukemia patients in a first complete remission (CR) were treated with two courses of consolidation chemotherapy (10-day BHAC-DMP, consisting of behenoyl cytosine arabinoside, daunorubicin, 6-mercaptopurine and prednisolone) and repeated maintenance-intensification therapy including eight cycles of six-day BHAC-DMP. G-CSF (filgrastim) was administered concurrently with these BHAC-DMP therapies. Toxicity during the therapeutic period was not significant in the study group compared with the historical control, treated with the same regimen without G-CSF. Neutrophil recovery after the consolidation therapy was more rapid in the study group than in the historical control (p = 0.066 and 0.024 for the first and second consolidation courses, respectively). Long-term toxicity, such as cytopenia, has not been seen in eight patients who have remained in CR for a long period (range: 39-58 months). At a median follow-up of 39 months, the predicted rate of 42-month CR duration for these 26 patients was 50% (95% confidence limits: 30% to 71%). We conclude that G-CSF-combined repeated BHAC-DMP postremission therapy is feasible. Full elucidation of the clinical benefit of this strategy will require further study.

P170 glycoprotein expression and impaired anthracycline retention in chronic myeloid leukaemia

Chronic myeloid leukaemia (CML) is a well known model of a disease refractory to chemotherapy, including anthracyclines and other drugs that are believed to be pumped out of the cells by a 170 Kd transmembrane glycoprotein (P170). In 35 cases of Ph+ CML we investigated the reactivity of leukaemic cells to a P170-directed monoclonal antibody (MRK-16), by means of flow cytometry. P170 overexpression was found in 4/14 (29%) chronic phase CML cases and in 16/23 (70%) accelerated and blastic phase CML cases (P = 0.01). The same cells were assayed for their ability to retain Daunorubicin and Idarubicin after 2-hours in vitro incubation with 1000 ng/ml of either drug. It was found that anthracycline cell concentration was negatively related with the degree of the reactivity to MRK-16. In accelerated and blastic phase, CML cells simultaneously expressed P170 and the stem cell related marker, CD34. These data confirm that Ph+ leukaemic cells overexpress P170, show that P170 overexpression is functionally relevant, and suggest that P170-related multidrug resistance may be an important factor for chemotherapy failure in Ph+ CML.

Evaluation of the clinical relevance of the anionic glutathione-s-transferase (GST pi) and multidrug resistance (mdr-1) gene coexpression in leukemias and lymphomas

By using RNA slot-blot technique, the frequency and the degree of GST pi and mdr-1 gene coexpression were investigated in 23 AML patients, 9 ALL, 9 CLL and 11 cases of NHL in an attempt to study their clinical and prognostic relevance. GST pi and mdr-1 levels were expressed as arbitrary units (U) with respect to the negative controls (U = 0), MCF7 and HL60 sensitive cell lines, and the positive controls (U = 10), MCF7/DOXO and HL60/DNR resistant cell lines. The concomitant GST pi/mdr-1 gene overexpression showed a negative prognostic value in the set of newly diagnosed AML pts (10 cases), furthermore higher GST pi and mdr-1 mRNA levels were averagely detected in the relapsed/resistant ALL pts (4 cases), and in CLL (7 cases) and NHL (8 cases) heavily pretreated patients who were unresponsive to chemotherapy and with a disease progression. These preliminary data show that two different mechanisms of drug resistance can be coexpressed at the same time in those leukemias and lymphomas with a clinically unfavourable course.

[Multidrug resistance induced by surexpression of the mdrl gene]

Drug resistance of some tumors and hematopoietic diseases is a major problem for clinicians. One of the mechanisms of resistance is called the multidrug resistance. Multidrug resistance is a cross-reactive resistance between molecules different in structure and activities. Multidrug resistance is characterized by an active drug efflux through the cell membrane with a decrease in drug cellular accumulation. This efflux out of the cell is due to a membrane glycoprotein called P-glycoprotein or P-gp 170 encoded by the mdr1 gene. In humans, high levels of mdr1 gene expression are observed in normal tissues as adrenal gland, colon and kidney. Tumors derived from these tissues are usually resistant to chemotherapy. By contrast to this intrinsic drug resistance, acquired drug resistance is defined by the mdr1 gene expression in tumors which relapse and become refractory to chemotherapy as acute lymphoïd and myeloïd leukemia, breast and ovarian cancers, non-Hodgkin lymphomas and multiple myeloma. When the clinical significance of multidrug resistance will be defined, identification of non-responders patients should lead to the use of therapeutic regimens including mdr reversing agents.