Osmotic microenvironments within tissue culture well plates are an important cause of variability in plant protoplast cultures

Summary To determine if the medium osmolality of plant protoplast cultures in 24-well tissue culture plates changes sufficiently during the culture period to affect development of the protoplasts the osmolality and the division of the protoplasts was monitored within the plates over a three week period. Large increases in osmolality were measured in cell-free experiments indicating that overall evaporation from the plates was substantial. The amount of evaporation from a given culture well depended on the position of the well within the plate; three microenvironments corresponding to the corner, edge, and middle positions of the plate consistently developed. Water placed in the recessed area between each culture well moderated the desiccation of the medium but did not eliminate the formation of microenvironments. The osmolality of the medium in protoplast cultures was higher than in the cell-free experiments but similar trends in terms of plate position were recorded. After 3 weeks of incubation of plates with water added between the wells, the osmolality of the medium in the protoplast cultures had increased 209 mOsm in the corner wells, had increased 77 mOsm in the edge wells, and had decreased 39 mOsm in the middle wells. As a result, there was a three-fold higher incidence of division of the protoplasts in the middle wells than in the corner wells. The non-uniformity of medium osmolality in protoplast cultures within tissue cultures well plates is important in experimental design, in the reproducibility of procedures between different laboratories, and in the preparation of replenishment medium for protoplast cultures to minimize osmotic shock. This work was supported by the College of Agriculture and Life Sciences and the Graduate School, University of Wisconsin-Madison; by McIntire-Stennis project WIS 3082; and by the USDA-Forest Service, North Central Forest Experiment Station (B. Haissig, Project Leader).