Subclonal heterogeneity of the multidrug resistance phenotype in a cell line expressing antisense MDR1 RNA.

A multidrug resistant (MDR) cell line was transfected with an antisense MDR1 expression vector and transfectant clones were analyzed for reversion of the MDR phenotype. Only one of 10 antisense-expressing transfectants showed a reduction in drug resistance, MDR1 mRNA and P-glycoprotein. Observations made using rhodamine-123, a fluorescent substrate for P-glycoprotein, revealed that dye retention in individual cells was highly variable within this antisense-expressing clone. Subpopulations were established from the original clone based on differences in rhodamine-123 retention. Rhodamine-123 retention varied inversely with levels of P-glycoprotein and MDR1 mRNA. All subpopulations expressed similar levels of antisense MDR1 RNA yet had dramatic differences in MDR1 mRNA levels. Analysis of vector integration site restriction fragment length polymorphisms confirmed that all populations originated from the same transfectant clone. Nuclear run-on analysis indicated that the mdr1 gene is transcribed at the same rate in all populations, suggesting that the reduction in MDR1 mRNA is mediated posttranscriptionally. Cells with the greatest reduction in MDR1 mRNA accumulate distinct antisense RNA transcripts in the nuclear RNA fraction, suggesting that antisense effectiveness in this system is associated with a nuclear event or process. These results reveal that antisense RNA activity is not necessarily distributed equally within a clonal population.

Enhanced sensitivity to G418 of human KB cells adapted to certain media and sera.

Sensitivity to the neomycin derivative G418 was determined for a human cell line, KB 3-1, that had been adapted to six different combinations of media and sera. The results indicate that while the plating efficiency is similar for all conditions, the susceptibility to G418 can differ markedly depending on the particular combination of media and sera used. This suggests that in experiments using neomycin resistance as a selectable marker, conditions may be found where the amount of G418 required for selection and maintenance of transfected cell lines can be reduced, providing a significant savings.