Permanent mycoplasma removal from tissue culture cells: A genetic approach

Abstract

Mycoplasma contamination of tissue culture cells easily evades detection and, thus, represents a continous threat to cell biologists. In cases where infected cell can not simply be replaced, attempts have to be made to eradicate mycoplasma from the tissue culture cells. A variety of anti-microbial agents have been shown to be toxic to mycoplasma strains; however, cell associated mycoplasmas are often protected from antibiotics at concentrations shown to be effectivein vitro. Antibiotic concentrations high enough to be lethal to cell asso|ciated mycoplasmas frequently are also detrimental to the host cells, while moderately increased antibiotic levels tolerated by the host cells often lead to only temporary growth suppression and/or to the emergence of mycoplasma strains resistant even to high concentrations of the antibiotic applied. Here, a genetic approach for the elimination of mycoplasma from tissue culture cells that overcomes these limitations is described. By expression of a selection marker conferring resistance to an otherwise toxic agent,Acholeplasma laidlawii infected BHK-21 cells used as the model system were enabled to temporarily tolerate antibiotic concentrations high enough to be lethal to cell associated mycoplasma while leaving the host cells unharmed. Upon successful mycoplasma eradication, cultivation of the cured host cells in the absence of the selective agent yielded revertant cell clones that had regained susceptibility to the toxic agent. Cessation of the selection marker expression was shown to result from the loss of the selection marker DNA, which is a consequence of the fact that the stable and permanent integration of foreign DNA in eucaryotic cell chromosomes is highly inefficient. Thus, the cells were cured from mycoplasma yet remained biochemically unaltered.