Abstract
Low-dose aspirin irreversibly acetylates cyclooxygenase (COX)-1 in anucleate platelets and progenitor megakaryocytes, permanently suppressing thromboxane (TX)A(2)-dependent platelet activation. Although aspirin pharmacodynamics is well characterized in platelets, the kinetics of COX inhibition and recovery in human megakaryocytes remains poorly defined, due to ethical issues associated with invasive, bone-marrow trephine sampling, and low megakaryocyte yield. We studied aspirin pharmacodynamics in human megakaryocytic cell lines as a reliable and feasible surrogate model. We characterized COX-1 and COX-2 expression and activity in MEG-01 and CHRF-288-11 megakaryocytic cell lines, treated with a range of aspirin concentrations and exposure duration. COX activity was quantified by the production of TXB(2) from exogenous arachidonic acid. A single 10-μM aspirin exposure suppressed TXB(2) by 90 ± 2% (MEG-01) and 85 ± 4% (CHRF-288-11), with full recovery within 48-72 hours. Both COX-isozymes were detected by western blot and immunohistochemistry; however, selective COX-1 inhibition by SC-560 reduced TXB(2) by >75%, whereas COX-2 inhibition by NS-398 had minimal effect. Repeated aspirin exposure every 24 hours produced concentration- and time-dependent TXB(2) suppression, achieving 89 ± 2% inhibition by day 2 at 1 μM and 73 ± 3% by day 4 at 0.1 μM. TXB(2) biosynthesis recovered by 86 ± 2% and 99 ± 10% at days 2 and 3, respectively. These findings identify COX-1 as the principal source of TXA(2) in megakaryocytes and demonstrate that aspirin inhibits megakaryocyte COX-1 time- and dose-dependently, with delayed recovery likely reflecting de novo synthesis of COX-1 protein, thereby providing mechanistic insight into the sustained antiplatelet effect of low-dose aspirin in humans. SIGNIFICANCE STATEMENT: In human megakaryocyte cell lines, once-daily aspirin treatment at low-concentration range time-dependently inhibits COX-1 with delayed recovery after aspirin withdrawal. This closely mimics the kinetics of platelets, supporting the translational utility of the megakaryocyte-based surrogate model.