MAB4122 Sigma-AldrichAnti-Multi-Drug Resistance Related Protein Antibody, clone MRPm6

The clinical relevance of multidrug resistance (MDR)-related proteins in childhood acute lymphoblastic leukemia (ALL) is largely unknown. The diversity of techniques, fixation methods, storage of cells (fresh or cryopreserved) etc, may contribute to discrepancies observed between several studies. We therefore optimized the detection of P-glycoprotein (P-gp), MDR-associated protein (MRP) and lung resistance-related protein (LRP) by immunocytochemistry and flow cytometry in childhood ALL cells. Thirteen fixation methods were compared using six antibodies in both immunocytochemistry and flow cytometry. The optimal fixation for P-gp (C219, MRK16), MRP (MRPr1) and LRP (LRP56) was a mixture of 2% (v/v) formaldehyde solution and acetone incubated for only 10 s at room temperature (FAc). For MRP recognized by MRPm6, the optimal fixation condition was acetone for 5 min at room temperature in immunocytochemistry, and methanol for 15 min at -20 degrees C in flow cytometry. P-gp staining by 4E3 was strongly antibody batch-dependent; on cytospins FAc fixation was optimal, but inconclusive data were obtained by flow cytometry. The optimized fixation conditions on fresh samples revealed a day-to-day variation in staining (both increasing and decreasing) in one third of the immunocytochemical tests. In flow cytometry the day-to-day variation in the fluorescence index was -1 +/- 22%. In both techniques, staining was comparable between fresh and cryopreserved cells. We recommend the use of the above mentioned fixation methods in order to study the clinical relevance of P-gp, MRP and LRP in childhood ALL.

The human multidrug resistance protein (MRP) is a 190 kd membrane glycoprotein that can cause resistance of human tumor cells to various anticancer drugs, by extruding these drugs out of the cell. Three different monoclonal antibodies, directed against different domains of MRP, allowed us to determine the localization of MRP in a panel of normal human tissues and malignant tumors. Whereas in malignant tumors strong plasma membrane MRP staining was frequently observed, in normal human tissues MRP staining was predominantly cytoplasmatic. Here, MRP was detected in several types of epithelia, muscle cells, and macrophages. From the presence of MRP in many epithelia we infer that MRP, like MDR1 P-glycoprotein, may have an excretory function in protecting the organism against xenobiotics. Recent studies indicate a role for MRP as a carrier for transport of glutathione-conjugated endo- and xenobiotics. The presence of MRP in bronchiolar epithelium, heart muscle, and macrophages would agree with the glutathione S-conjugate carrier activity previously detected in these cells. Furthermore, in 46 of 119 untreated tumors from various histogenetic origins MRP staining was seen. In these tumors MRP may contribute to the intrinsic resistance against treatment with chemotherapeutic drugs.

Melanoma cells often display a multidrug-resistant phenotype, but the mechanisms involved are largely unknown. We have studied here the recently identified transport-associated proteins, MRP and LRP, and the well-known drug resistance marker P-glycoprotein using a panel of 16 human melanoma cell lines and 71 benign and malignant melanocytic tissue samples. By flow cytometry and immunohistochemistry, expression of P-glycoprotein was not detectable on the protein level in the 10 cell lines analyzed, although by reverse transcriptase polymerase chain reaction, MDR-1 gene expression was demonstrated in 2 of 10 cell lines. In addition, immunohistology revealed P-glycoprotein expression in only 1 of 71 melanocytic lesions. In contrast, MRP was detected in a subset of melanoma cell lines by reverse transcriptase polymerase chain reaction and immunohistology (4 of 10). LRP expression was observed in 8 of 10 melanoma cell lines by immunochemistry and in 10 of 10 by reverse transcriptase polymerase chain reaction. Furthermore, MRP was detected immunohistologically in almost 50% of primary and metastatic melanoma specimens, although no significant differences were found between metastases taken before or after chemotherapy. Expression of LRP was detected in a subset of nevi with nevus cells exhibiting up to 25% positive LRP reactivity. In 13 of 21 primary melanomas and 23 of 37 metastases, more than 25% of tumor cells were stained by the LRP-56 monoclonal antibody. Particularly in the group of metastases with more than 50% of LRP-positive cells, 7 of 11 of the metastases had been previously exposed to chemotherapeutic drugs. Although the expression of membrane transport proteins may explain only the chemoresistance toward lipophilic, natural compounds and not resistance against alkylating agents, the lack of P-glycoprotein expression after chemotherapeutic treatment and the significant expression of MRP and LRP in melanoma cells provide first insights into the drug-resistant phenotype in melanoma. Additional studies analyzing the role of MRP and LRP in chemoresistance of melanoma are warranted.