Transformation efficiency refers to the ability of a cell to take up and incorporate exogenous DNA, such as plasmids, during a process called transformation. The efficiency of transformation is typically measured as the number of transformants (cells that have taken up the exogenous DNA) per microgram of DNA added to the cells. A higher transformation efficiency means that more cells are able to take up the DNA, and a lower efficiency means that fewer cells are able to do so. In molecular biology, transformation efficiency is a crucial parameter, it is used to evaluate the ability of different methods to introduce plasmid DNA into cells and to compare the efficiency of different plasmid, vectors and host cells. This efficiency can be affected by a number of factors, including the method used for introducing the DNA, the type of cell and plasmid used, and the conditions under which the transformation is performed. Therefore, measuring and optimizing transformation efficiency is an important step in many molecular biology applications, including genetic engineering, gene therapy and biotechnology. By measuring the transformation efficiency, we can utilize the information from our experiment to evaluate how effectively our transformation went. This is a quantification of how many cells were altered by 1 μg of plasmid DNA. In essence, it is a sign that the transformation experiment was successful. It should be determined under conditions of cell excess. Transformation efficiency is typically measured as the number of transformed cells per total number of cells. It can be represented as a percentage or as colony forming units (CFUs) per microgram of DNA. One of the most common ways to measure transformation efficiency is by performing a colony forming assay. Here is an example of how to calculate transformation efficiency using colony forming units (CFUs): Plate a known number of cells on agar plates containing the appropriate antibiotics. Incubate the plates for a period of time (usually overnight) at the appropriate temperature and conditions for the cells.
Giovanni Dietler, Julien Dorier, Yannis Burnier, Fabrizio Benedetti, Andrzej Stasiak, Aleksandre Japaridze, Robert Sebastian Kwapich