Oxidative Stress, Gene Expression, and Protein Changes Induced in the Human Placenta during Labor

Tereza Cindrova-Davies^*, Hong-Wa Yung^*, Jemma Johns, Olivera Spasic-Boskovic^*, Svitlana Korolchuk^*, Eric Jauniaux, Graham J. Burton^* and D. Stephen Charnock-Jones

From the Departments of Physiology, Development, and Neuroscience,^* and Obstetrics and Gynaecology, University of Cambridge, Cambridge; and the Academic Department of Obstetrics and Gynaecology, Royal Free and University College, London, United Kingdom

Malperfusion of the placenta has been implicated as a causeof oxidative stress in complications of human pregnancy, leadingto release of proinflammatory cytokines and anti-angiogenicfactors into the maternal circulation. Uterine contractionsduring labor are known to be associated with intermittent utero-placentalperfusion. We therefore tested whether oxidative stress, proinflammatorycytokines, and angiogenic regulators were increased in placentassubjected to short (<5 hours) and long (>15 hours) laborcompared with nonlabored controls delivered by cesarean section.In addition, broader changes in gene transcripts were assessedby microarray analysis. Oxidative stress, activation of thenuclear factor- ${kappa}$ B pathway, tumor necrosis factor- ${alpha}$ and interleukin1ß all increased in placental tissues after labor.Stabilization of hypoxia-inducible factor-1 ${alpha}$ and increased vascularendothelial growth factor soluble receptor-1 were also observed.By contrast, tissue levels of placenta growth factor decreased.Apoptosis was also activated in labored placentas. The magnitudeof these changes related to the duration of labor. After labor,55 gene transcripts were up-regulated and 35 down-regulated,and many of these changes were reflected at the protein level.In conclusion, labor is a powerful inducer of placental oxidativestress, inflammatory cytokines, and angiogenic regulators. Ourfindings are consistent with intermittent perfusion being theinitiating cause. Placentas subjected to labor do not reflectthe normal in vivo state at the molecular level.