Prognostic significance of multidrug resistance gene 1 (MDR1), multidrug resistance-related protein (MRP) and lung resistance protein (LRP) mRNA expression in acute leukemia

The prognostic significance of multidrug resistance (MDR) gene expression is controversial. We investigated whether multidrug resistance gene 1 (MDR1), multidrug resistance-related protein (MRP) and lung resistance protein (LRP) mRNA expression are associated with outcomes in acute leukemia patients. At diagnosis we examined MDR1, MRP and LRP mRNA expression in bone marrow samples from 71 acute leukemia patients (39 myeloid, 32 lymphoblastic) using nested RT-PCR. The expression of each of these genes was then expressed as a ratio in relation to beta-actin gene expression, and the three genes were categorized as being either 0, 1+, 2+ or 3+. MDR1, MRP and LRP mRNA expression was detected in 23.9%, 83.1% and 45.1 %, respectively. LRP mRNA expression was significantly associated with resistance to induction chemotherapy in acute leukemia patients, and in the AML proportion (p=0.02 and p=0.03, respectively). MRP and high MDR1 mRNA expression was associated with poorer 2-yr survival (p=0.049 and p=0.04, respectively). Patients expressing both MRP and LRP mRNA had poorer outcomes and had worse 2-yr survival. The present data suggest that MDR expression affects complete remission and survival rates in acute leukemia patients. Thus, determination of MDR gene expression at diagnosis appears likely to provide useful prognostic information for acute leukemia patients.     

Multi-drug resistance (MDR1) gene expression in de novo acute leukemia cells: correlations with CD surface markers and treatment outcome.

One important mechanism of drug resistance in acute leukemia is the overexpression of the multi-drug resistance (MDR1) gene that encodes a 170-kDa membrane protein called P-glycoprotein. To estimate the incidence and role of MDR1 gene expression in patients with acute leukemia, we investigated the expression of MDR1 by using the RT-PCR method in blast cells from 40 cases of de novo acute leukemia. We found a high frequency of MDR1 gene expression: 10 out of 20 with de novo acute myeloid leukemia (AML), 8 out of 17 with de novo acute lymphoblastic leukemia (ALL), and none of the 3 with de novo acute mixed leukemia, were MDR1 mRNA-positive. No correlation between cluster designation (CD) surface markers (CD19, CD7, CD13, CD33, CD34, CD14, HLA-DR) and MDR1 gene expression in AML was found. The complete remission rate was correlated with MDR1 gene expression. Among 40 evaluable patients examined, 17% (3 of 18) with MDR1 mRNA-positive reached complete remission versus 77% (17 of 22) with MDR1 mRNA-negative (p=0.044). These results suggest that MDR1 gene expression can be used as a prognostic factor and may be helpful in determining chemotherapeutic protocol for patients with acute leukemia.     

急性髓细胞白血病患者CD56抗原表达与MDR1基因表达量的关系研究

目的 研究初治急性髓细胞白血病(AML)患者CD56抗原表达与多药耐药(MDR)1基因表达量的关系,探讨CD56抗原表达与MDR1基因表达量在AML耐药中的作用及相互关系.方法 采用流式细胞术(FCM)和建立实时荧光定量PCR技术分别检测79例AML患者CD56抗原表达及MDR1基因表达水平并分析两者之间的关系及临床意义.结果 24.1%AML患者表达CD56抗原,FAB亚型中M5 AML患者表达阳性率高于其他亚型.遗传学危险度分级高危组患者CD56抗原表达阳性率显著高于中危组(P<0.01),伴t(8:21)AML患者CD56抗原表达阳性率(57.1%)显著高于其他低危组AML(P<0.05).CD56抗原表达阳性初治AML患者MDR1基因表达水平显著高于表达阴性患者(P<0.001).MDR1基因高表达且CD56抗原阳性AML组的CR率(58.8%)显著低于MDR1基因低表达且CD56表达阴性组(89.2%,P<0.01).结论 AML患者CD56抗原表达与MDR1基因表达水平存在相关性;同时定量检测MDR1基因表达及CD56抗原表达更有助于判断预后.     

Expression of genes related to multiple drug resistance and apoptosis in acute leukemia: response to induction chemotherapy

Resistance to chemotherapy is a major impediment to the successful treatment of acute leukemia (AL). Expression of genes involved in drug resistance and apoptosis may be responsible for this. This study aimed to investigate the expression of drug resistance (MDR1, MRP1, LRP, BCRP, GSTP1, DHFR) and apoptotic genes (p53, BCL-2, Survivin) in adult acute leukemias and compare them with clinical and hematological findings and response to induction chemotherapy. Eighty-five patients with AL [45 with acute myeloid leukemia (AML) and 40 with acute lymphoblastic leukemia (ALL)] were used as a study group. Real-time PCR results showed that expression level of MDR1 was significantly higher in AML whereas expression of DHFR, BCRP and Survivin was significantly higher in ALL patients. In AML, significant correlation was observed between LRP and MRP1 (r(s)=0.44, p=0.016), LRP and DHFR (r(s)=0.41, p=0.02), MDR1 and BCL-2 (r(s)=0.38, p=0.03). Expression of GSTP1 and LRP correlated with high white blood count (p=0.03 and p=0.03) and BCL-2 with high peripheral blast count (p=0.009). MDR1 expression was significantly associated with the expression of immature stem cell marker CD34 (p=0.002). In ALL, significant association was found between LRP gene and female sex (p<0.0001), LRP and B-ALL patients (p=0.04) and LRP and BCR/ABL positive patients (p=0.004). High expression of MDR1 and BCL-2 in AML and MRP1 gene in ALL was associated with response to induction chemotherapy (p=0.001, p=0.02 and p=0.007 respectively). These results showed the potential clinical relevance of MDR1, MRP1 and BCL-2 in adult patients with acute leukemia in the context of induction chemotherapy.     

Expression of Toll-like receptor 9 in bone marrow cells of myelodysplastic syndromes is down-regulated during transformation to overt leukemia

Toll-like receptors (TLRs) play a crucial role in the host defense against invading microorganisms by recognizing pathogen-associated molecular patterns. Recently, a number of endogenous molecules have been reported to be ligands of TLRs. Some of these molecules are known to be expressed in cancer tissue and activate intracellular signal pathways via TLRs during cancer progression. Thus, in the present study, we analyzed the expression dynamics of TLRs in the bone marrow of myelodysplastic syndromes (MDS) during the course of transformation to overt leukemia (OL) using real-time RT-PCR. MDS bone marrow cells at the time of initial diagnosis tended to express higher levels of TLR2, TLR4 and TLR9 than control bone marrow cells. Among these TLRs, TLR9 exhibited a significant decrease of expression at the time of transformation to OL. The expression of TLR9 and TNF-α showed significant correlation in bone marrow cells from patients with MDS and OL. Immunohistochemically, TLR2 was mostly localized to neutrophils of the control and MDS bone marrow. TLR4 was observed in a subset of neutrophils and a few mononuclear cells in control and MDS bone marrow. In addition, TLR4 was weakly expressed in nearly half of immature myeloid cells of MDS cases. TLR9 was mainly localized to neutrophils in the control and RA bone marrow and strongly expressed in the immature myeloid cells of RAEB cases, although the blastic cells of OL cases did not express TLR9. Bone marrow cells in MDS exhibit frequent apoptosis, while OL cells are prone to be immortal. Thus, TLR9 might be associated with regulation of apoptotic/proliferative signals via TNF-α in the MDS bone marrow.     

Unregulated activation of STAT-5, ERK1/2 and c-Fos may contribute to the phenotypic transformation from myelodysplastic syndrome to acute leukaemia

Myelodysplastic syndrome (MDS) is characterised by ineffective erythropoiesis and poor progenitor response to erythropoietin (Epo). The aim of this study was to determine the role of the Epo-R mediated signalling in the rise of MDS and whether alteration of signalling pathways contribute to the leukeamogenesis from MDS to acute leukaemia. We analysed Epo and GM-CSF induced ERK1/2 activation, c-Fos expression, STAT-5 and AP-1 DNA binding activities in mononuclear cells of umbilical cord blood (UCBMNC), normal marrow (NBMMNC) or marrow with MDS, AML with prior MDS and de novo AML. In UCBMNC and NBMMNC, Epo and GM-CSF induced the activation of STAT-5 DNA binding and ERK 1/2 activation (n = 6). In contrast, in MDS RA, both signalling pathways were activated only by GM-CSF but not by Epo (n = 7). In acute leukaemia, elevated basal activity of STAT-5 DNA binding appeared in 8/8 cases, which was independent of Epo or GM-CSF treatment. In normal and MDS samples, c-Fos and Egr-1 proteins were not detectable and the expression levels were not increased by Epo or GM-CSF treatment. In contrast, we found an elevated level of c-Fos expression in 5/8 acute leukemia cases, which was not further increased in the presence of Epo or GM-CSF. The elevated c-Fos expression was accompanied by an extremely high blast number in 5/5 cases. These results suggest that impaired ERK/MAPK activation, similarly to impaired STAT-5 activation in Epo-R signalling, may be responsible for the apoptotic process and the block of maturation in MDS RA. The results also suggest that the appearance of the constitutively activated STAT-5 DNA binding and c-Fos expression may be used as a predictor of the blastic transformation.     

p53 expression in myeloid cells of myelodysplastic syndromes. Association with evolution of overt leukemia.

To assess p53 expression in the hematopoietic cells of the bone marrow in premalignant as well as malignant conditions, we examined immunohistochemically bone marrow biopsies from patients with myelodysplastic syndromes (MDS, n = 51), acute myeloid leukemia (n = 42) and as a nonneoplastic condition, aplastic anemia (n = 20) and samples from individuals who had no hematological disorder (control, n = 12). Nuclear accumulation of p53 protein was found in seven of 51 patients with MDS (14%) and two of 42 acute myeloid leukemia patients (5%), whereas patients with aplastic anemia and control subjects were uniformly negative for p53 protein. In the bone marrow of patient with MDS, p53-positive cells constituted about 5 to 30% of the total bone marrow cells. Two-color immunohistochemical analysis revealed that the p53-positive cells were also positive for the myeloid cell marker. Half of the MDS cases that evolved to overt leukemia (seven of 14) exhibited positive p53 reaction in the bone marrow at the time of initial diagnosis. This frequency (50%) was significantly higher than that in de novo acute myeloid leukemia cases. All of the seven MDS cases that exhibited p53 expression at the time of initial diagnosis developed overt leukemia later, and p53 expression was maintained throughout the progression of MDS. The results suggest that p53 mutations that occur in the myeloid cells in MDS may confer a growth advantage to these cells resulting in the progression to overt leukemia. Thus, immunohistochemical examination for p53 is very useful for predicting the evolution to overt leukemia from MDS.     

Differences in CD33 intensity between various myeloid neoplasms

We measured the concentration of CD33 antigen on the surface of cells in 315 bone marrow (BM) samples and 114 corresponding peripheral blood (PB) samples from patients with various leukemias (acute myeloid leukemia [AML], chronic myelogenous leukemia [CML], myeloproliferative disorder [MPD] other than CML, myelodysplastic syndrome [MDS]) and from control subjects. Overall CD33 intensity in total CD33+ cells was significantly higher in BM than in PB. CD33 intensity in total BM CD33+ cells differed significantly with the type of disease. The median number of CD33 molecules per cell was highest in AML, followed by MDS, CML, and control subjects and lowest in MPD. When only CD34+/CD33+ cells were examined, CD33 molecules per cell were highest in CD34+ cells in AML and lowest in MPD (P = .027). Patients with AML or MDS younger than 60 years had significantly higher intensity of CD33 expression on CD34+ cells than patients 60 years or older. Levels of CD33 intensity did not correlate with cytogenetics in patients with AML or MDS. There was no correlation between CD33 intensity and response to therapy or overall survival in 35 patients treated with protocols including Mylotarg. These data demonstrate variation in CD33 intensity between various leukemias.     

Immunohistochemical detection of p53, mdm2, waf1/p21, and Ki67 proteins in bone marrow biopsies in myelodysplastic syndroms, acute myelogenous leukaemias and chronic myeloproliferative disorders

The aim oof this study was to investigate the immunohistochemical expression of p53, mdm2, and waf1/p21 proteins in myelodysplastic syndromes (MDS), acute myelogenous leukaemias (AML), and chronic myeloproliferative disorders (CMPD). Paraffin-sections of bone marrow biopsies from 30 cases of MDS (6 cases of RAEB and RAEB-T) 22 AML (4 cases occurring in the setting of MDS), 16 chronic myeloproliferative disorders (CMPD), and 10 cases without alterations were investigated by immunohistochemistry for p53, waf1/p21, mdm2 and Ki67 proteins. P53 was detected in immature myeloid cells in 6/30 MDS (20%) and in 6/22 AML (27%) while it was not expressed in CMPD. Of the 6 p53 positive AML, 3 occurred as evolution of MDS and 3 were de novo acute leukaemias. Waf1/p21 was detected in 5/22 (23%) AML in immature myeloid cells. Waf1/p21 was also expressed in 18/30 (60%) MDS and 10/16 (63%) CMPD in variable proportion (5-25%) of the mature myeloid cells and megakaryocytes. Waf1/p21 was not detected in immature myeloid cells in MDS and CMPD. Mdm2 protein was expressed in 3/30 (10%) MDS in the immature myeloid cells and in 1/22 AML in blastic cells. The combined immunophenotypes of immature myeloid cells of MDS were: p53+/mdm2+/waf1-: 3, p53+/mdm2-/waf1-: 3, while the immunohistochemical patterns of AML were: p53+/mdm2-/waf1-: 4, p53+/mdm2+/waf1+: 1, p53+/mdm2-/waf1+: 1, p53-/mdm2-/waf1+: 3. Ki67/MIB1 staining was found in at least 30% of immature myeloid cells in MDS and AML and in at least 20% of these cells in CMPD. In conclusion, our results indicate that p53 protein is overexpressed in the myeloid lineage in a proportion of AML and MDS, while is not detected in CMPD and normal bone marrow, p53 expression was much more frequent in AML occurring as an evolution of MDS than in de novo AML. The combined immunophenotypes of p53 positive AML and MDS suggest that p53 overexpression may be due to mutation, in some AML and MDS cases with the p53+/mdm2-/waf1- phenotype. However, it would be also possible that p53 protein accumulation is not related to p53 mutation but to inhibition of p53/mdm2 binding due to mdm2 defects and/or other events related to cell stress signals. On the other hand, waf1/p21 protein overexpression without p53 expression in some AML could be p53-independent and may represent an attempt to control the high proliferation rate which was evidenced by Ki67/MIB1 immunostaining. However, the possibility of p21 to arrest cell-cycle, in these cases of AML, seems to be overridden, suggesting that cell-cycle deregulation may be involved in a proportion of AML.     

Low frequency of FLT3 gene internal tandem duplication and activating loop mutation in therapy-related acute myelocyticleukemia and myelodysplastic syndrome

FLT3 gene internal tandem duplication (ITD) and activating loop mutations (D835) were determined in 22 cases of therapy-related acute myelocytic leukemia/myelodysplastic syndrome (t-AML/MDS) and 102 cases of de novo AML/MDS. In t-AML/MDS, FLT3 ITD was absent, and D835 was found in only one case of therapy-related acute promyelocytic leukemia (APL). In de novo AML/MDS, however, FLT3 ITD and D835 were significantly more frequent (28 of 102 cases, P=0.024) and were associated with high peripheral blood and marrow blast counts. Our results suggest that different pathogenetic pathways might be involved in t-AML/MDS and de novo AML/MDS.     

Therapy-related acute myeloid leukemia/myelodysplasia with balanced 21q22 translocations

The morphologic and immunophenotypic findings of 36 cases of 21q22 acute myeloid leukemia (AML) and myelodysplasia (MDS) were compared, including 14 de novo t(8;21) AMLs, 11 t(8;21) therapy-related AML/MDS cases, and 11 therapy-related AML/MDS cases with other 21q22 balanced translocations [t(n;21)]. Cases were evaluated for the presence of Auer rods, distinct chunky cytoplasmic blast cell granules, promyelocyte increase, cytoplasmic perinuclear clearing (hofs) of blast cells, eosinophil increase, andfeatures of associated trilineage dysplasia. Results of immunophenotyping studies for CD19, CD34, and CD56 expression were compared. Cases of de novo and therapy-related t(8;21) disease shared common morphologic features of chunky cytoplasmic granules, perinuclear hofs, and promyelocyte increases that were not seen consistently in the t(n;21) group of t-AML/MDS cases. Immunophenotypic similarities also were observed between the 2 t(8;21) groups. De novo and therapy-related t(8;21) disease, however, differed by the frequent presence of associated dysplasia in both t-AML/MDS groups, which was infrequent in the de novo t(8;21) group. Therapy-related AMI/MDS with t(8;21) shares characteristic morphologic and immunophenotypic features with de novo t(8;21) AML, but frequently also occurs with associated myelodysplastic changes, similar to other therapy-related acute leukemias.     

Myelodysplastic syndrome with inv(3)(q21q26.2) or t(3;3)(q21;q26.2) has a high risk for progression to acute myeloid leukemia

Acute myeloid leukemia (AML) with inv(3) (q21q26.2) or t(3;3)(q21;q26.2) is a distinct subtype in the World Health Organization classification. The natural history of myelodysplastic syndrome (MDS) associated with these cytogenetic aberrations is poorly understood. We studied 17 MDS (11 de novo and 6 therapy related) and 3 chronic myelomonocytic leukemia (CMML) cases associated with inv(3) (q21q26.2) or t(3;3)(q21;q26.2). The de novo cases were further classified as refractory cytopenia with multilineage dysplasia (n = 8) and refractory anemia with excess blasts (n = 3). Isolated inv(3)/t(3;3) was identified in 4 cases, whereas -7/7q (n = 13) and -5/5q (n = 6) were common additional aberrations. Nineteen patients died, including 13 in whom the disease progressed to AML after a median of 7 months. Median survival for patients with de novo disease was similar to that for patients with therapy-related MDS (13 vs 17.5 months). MDS or CMML with inv(3)/t(3;3) are aggressive diseases with a high risk of progression to AML.     

Expression of multidrug resistance-associated proteins in rhabdomyosarcomas before and after chemotherapy: the relationship between lung resistance-related protein (LRP) and differentiation

Rhabdomyosarcomas generally respond well to chemotherapy, and the residual lesions often are better differentiated than their primaries. This phenomenon may be explained by selective multidrug resistance (MDR) of differentiated tumor cell populations. We assess the role of MDR proteins in chemotherapy-induced differentiation in rhabdomyosarcomas in a clinical setting. Paraffin-embedded samples of 13 pairs of primary untreated rhabdomyosarcomas and their residual, recurrent, or metastatic lesions after chemotherapy were assessed for expression of MDR proteins, including P-glycoprotein (Pgp), multidrug resistance-associated protein (MRP-1), and lung resistance-related protein (LRP). Expression was semiquantitatively scored based on the percentage of isolated immunoreactive tumor cells as follows: 0, negative; 0.5, <5%; 1, 5% to 25%; 2, 26% to 50%; 3, 51% to 75%, and 4, >75%. All specimens after chemotherapy, except the late recurrences, were better differentiated than their primary, untreated specimens. Pgp or MRP-1 expression did not change significantly, but LRP expression increased significantly after chemotherapy. In both untreated and treated samples, LRP was expressed primarily in differentiated cells. The findings indicate that the in vivo expression of LRP, but not of Pgp and MRP-1, is induced by chemotherapeutic treatment in rhabdomyosarcomas. The preferential expression of LRP in differentiated cells and the subsequent more extensive expression after chemotherapy suggests that LRP plays a role in therapy-induced differentiation.     

Cell-cycle progression rates and sister chromatid exchange frequencies in the bone marrow of patients with myelodysplastic syndrome and acute myeloid leukemia.

The proliferation characteristics of leukemic cells may be a determining factor in disease course and response to therapy. The present study compares the rate of cell-cycle progression in the bone marrow of 16 hematologically normal subjects, 19 patients with acute myeloid leukemia (AML), and 23 patients with myelodysplastic syndrome (MDS). The frequency of sister chromatid exchanges (SCE) in bone marrow cells is also compared. MDS and AML patients showed a reduction in the rate of cell-cycle progression compared with normal subjects. Patients with 'high risk' MDS (RAEB/RAEB-t) did not differ significantly from patients with AML but had a significantly slower rate of cell-cycle progression than patients with 'low-risk' MDS (PASA/RA). There was no correlation between the rate of cell-cycle progression and clonal karyotype status or the percentage of blast cells in either MDS or AML. There were no significant differences in SCE frequency between normal subjects and MDS or AML patients.     

急性髓系白血病患者化疗后微小残留病与多药耐药基因表达相关

目的明确急性髓系白血病(AML)中微小残留病(MRD)与多药耐药基因表达的相关性。方法收集初诊AML患者骨髓52例,用real-time PCR检测患者化疗前ABCB1、ABCC1、ABCC4及ABCG2 4种多药耐药基因的表达,同时用多参数流式细胞术(MFC)检测患者诱导化疗后和化疗3、6和9个月后的MRD表达水平。结果 52例AML患者MRD表达水平与ABCB1(P0.01)、ABCC1(P0.01)、ABCC4(P0.01)和ABCG2(P0.01)的mRNA表达水平具有明显相关性。持续监测9个月后,MRD再次转阳者ABC基因表达水平显著高于持续阴性者:ABCB1(P0.05)、ABCC1(P0.05)、ABCC4(P0.01)和ABCG2(P0.01)。结论 MRD表达水平与多药耐药基因表达水平显著正相关。