Ischemia-Triggered Translocation and Inactivation of Protein Kinase C Isoforms in the Fetal Brain

Abstract: The kinetics of protein kinase C (PKC) translocation and down-regulation in the 20-day-old fetal brain following short and long episodes of maternal-fetal blood flow occlusion were examined. Restriction for up to 15 min increased the specific enzymatic activity in the membrane by 73%, indicative of translocation. After a 30-min restriction and a 2.5-h reperfusion the total PKC activity in the cytosol was reduced to ～50%, consistent with down-regulation/inactivation. The total membrane PKC activity remained unchanged. Several PKC isoenzymes, including α, β1, β2, ε, and ζ, but not γ, were identified in the fetal brain on western blots using specific antibodies. Compared with postnatal day 15, a greater proportion of the fetal PKC isoforms, particularly α and ε, were membrane bound. α, β2, ε, and ζ, but not β1, were translocated into the membrane compartment after episodes of ischemia alone or ischemia and reperfusion. There were no major identifiable proteolytic fragments in the 50-kDa region. Major losses in the total enzymatic activity were encountered in both cytosol and membrane fractions after storage of the enzyme for 10 days at 4°C. These losses were less profound in membrane fractions from ischemic than control animals, suggesting a relative sparing of activity in the membrane as a result of the insult. Preincubation of DEAE-purified PKC for 30 min at 50°C resulted in enzyme inactivation. This was accompanied by a size reduction (～2–5 kDa) in the gel migration of several isozymes in both cytosol and membrane fractions. At 42°C, although the molecular size was apparently reduced, limited PKC activity was observed, suggesting either that the two processes are not mutually related or that certain PKC isoforms can act after partial modification. The data suggest that ischemic episodes stimulate two apparently adverse processes in the PKC signal transduction cascade: a decline in the cytosol and a sparing of the membrane-translocated PKC activity. The latter may provide an important regulatory mechanism for PKC long-term activation in nerve cells.