Some aspects of the causes of enhanced immune response of in vitro frozen ascites fibrosarcoma tumor cells in mice.

Estimation of 3 M KCl-extracted ascites fibrosarcoma (AFS) tumor cell membrane peripheral proteins in native and frozen tumor cells showed approximately a three-, four-, and fivefold increase per 1 x 10(6) cells of single-, three-, and programmed three-cycle frozen AFS tumor cells, respectively, compared to the same number of native cells, indicating an increase in surface membrane protein concentration with freezing. The 10% gel (homogeneous) electrophoretic (SDS-PAGE) study of 3 M KCl-extracted native and frozen cell membrane proteins showed (i) membrane proteins of native cells resolve into many more components compared to those of any frozen membranes, i.e., single, three, and programmed three cycle, the components decreasing in that order; (ii) the concentration of larger-molecular-weight protein fractions (> or = 75 kDa) decreases while those of smaller fractions (14 to 24 kDa) increase in frozen cells, with the maximum being in the programmed three-cycle frozen group. In contrast, the native cell membrane is rich in higher-molecular-weight proteins (> or = 75 kDa) with concentrations slowly decreasing toward lower-molecular weight fractions. Thus, the probable reasons for increased immune response of animals immunized with frozen AFS tumor cells are (i) absolute increase in cell surface protein concentrations as given by 3 M KCl extraction of cell membrane peripheral protein estimation in AFS tumor cells postfreeze; (ii) cell-surface protein pattern which is heterogeneous before freezing becomes relatively more homogeneous following freezing of AFS tumor cells; and (iii) depolymerization and breaking of higher-molecular-weight components which increase the concentration of terminal-sequence antigenic determinants and increase accessibility of determinant grouping by removing steric hindrance following freezing.