Abstract
High-altitude (HA) hypoxia lowers uterine artery (UtA) blood flow during pregnancy and birth weight. Adenosine monophosphate kinase (AMPK) activation has selective, uteroplacental vasodilator effects that lessen hypoxia-associated birth weight reductions. In this study, we determined the relationship between AMPK-pathway gene expression and metabolites in the maternal circulation during HA pregnancy as well as with the maintenance of UtA blood flow and birth weight at HA. Residents at HA (2,793 m) versus low altitude (LA; 1,640 m) had smaller UtA diameters at weeks 20 and 34, lower UtA blood flow at week 20, and lower birth weight babies. At week 34, women residing at HA versus women residing at LA had decreased expression of upstream and downstream AMPK-pathway genes. Expression of the α(1)-AMPK catalytic subunit, PRKAA1, correlated positively with UtA diameter and blood flow at weeks 20 (HA) and 34 (LA). Downstream AMPK-pathway gene expression positively correlated with week 20 fetal biometry at both altitudes and with UtA diameter and birth weight at LA. Reduced gene expression of AMPK activators and downstream targets in women residing at HA versus women residing at LA, together with positive correlations between PRKAA1 gene expression, UtA diameter, and blood flow suggest that greater sensitivity to AMPK activation at midgestation at HA may help offset later depressant effects of hypoxia on fetal growth.NEW & NOTEWORTHY Fetal growth restriction (FGR) is increased and uterine artery (UtA) blood flow is lower at high altitudes (HA) but not all HA pregnancies have FGR. Here we show that greater UtA diameter and blood flow at week 20 are positively correlated with higher expression of the gene encoding the α(1)-catalytic subunit of AMP protein kinase, PRKAA1, suggesting that increased AMPK activation may help to prevent the detrimental effects of chronic hypoxia on fetal growth.