However, the colorectal carcinoma cell lines HCT-15, DLD-1, LS 17

However, the colorectal carcinoma cell lines HCT-15, DLD-1, LS 174 T, and LoVo cells that express Mdr-1 are growth inhibited by 17-AAG. We used Colo

320 cells as a positive control for Mdr-1 expression. MRP1 expression could be barely detected Dorsomorphin nmr only in DLD-1 cells, which respond to 17-AAG. T98G cells were used as a positive control. On the contrary, BCRP1 expression was detected mainly in the sensitive Hs 766 T pancreatic carcinoma cells and to a lesser extent in several colorectal carcinoma cell lines: DLD-1, SW480, LS 174 T, SW620, HCT-15, and HGUE-C-1 sensitive to 17-AAG and in Caco-2 cells resistant to 17-AAG. The 17-AAG–resistant PANC-1 and CFPAC-1 cells do not express any of the ABC transporters used in our study. We wanted to confirm whether NQO1 was involved in the intrinsic resistance to 17-AAG found by others in pancreatic cancer cell lines [39] and to determine its role in our panel of pancreatic and colorectal carcinoma cell lines and primary tumor cell cultures. The protein NQO1 levels and enzymatic activity were undetectable in the 17-AAG–resistant CFPAC-1 and PANC-1 pancreatic

carcinoma cells and in Caco-2 colorectal cells, which are 17-AAG–resistant (Figure 8, A and B). In fact, there was a negative correlation between the IC50 for 17-AAG after 72 hours of drug exposure and NQO1 activity in the pancreatic and colorectal carcinoma cells studied ( Figure 8C). In addition, the primary cell cultures derived from colorectal tumors express different levels of NQO1 and Hsp70 ( Figure 8A). Interestingly, NQO1 protein levels were relatively high in the less sensitive primary culture to both 17-AAG and NVP-AUY922, HCUVA-CC-34. As expected, there was no Tofacitinib cell line correlation between the IC50 for NVP-AUY922 and NQO1 enzymatic activity in the pancreatic and colorectal carcinoma cell lines studied ( Figure 8C). To determine the role of NQO1 in sensitivity to 17-AAG, we performed cell proliferation assays in 17-AAG–sensitive cell lines in the presence of the NQO1-specific inhibitor ES936 [5-methoxy-1,2-dimethyl-3-[(4-nitrophenoxy)methyl]indole-4,7-dione], which

was added 30 minutes before exposure to 17-AAG and sustained throughout 17-AAG treatment for 72 hours. In spite of significantly reducing NQO1 activity (Figure 8B), this inhibitor was unable to confer 17-AAG resistance to sensitive cells ( Figure 9A). As expected, no effect was observed in cell lines devoid of NQO1 of protein or enzymatic activity, such as CFPAC-1, PANC-1, or Caco-2 cells (data not shown). Then, we wanted to determine the effects of NQO1 ablation in long-term clonogenic assays. First, we determined that after 4 fours of treatment with ES936, NQO1 activity was still inhibited ( Figure 9D). Then, we performed clonogenic experiments after incubating HT-29 cells for 4 hours with 17-AAG or a combination of the specific inhibitor ES936 and 17-AAG and found that clonogenic survival of cells was only slightly recovered after the combination treatment ( Figure 9, B and C).

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