Role of sympathetic innervation on cerebral artery remodeling during chronic hypoxia in fetal lambs (853.3)

Cerebral arteries adapt to chronic hypoxia by altering the phenotypes of the plastic and heterogeneous population of cells in the artery wall. Perivascular nerves also undergo differentiation during hypoxia and alter vasotrophic effects on arteries. Here we test the hypothesis that nerves from the superior cervical ganglia (SCG) mediate hypoxic remodeling of ovine cerebral arteries. Using a chronic hypoxia (CH) and unilateral sympathectomy (SANX) model, we tested effects of CH and SANX on tone, contractile proteins and cell proliferation. Contractile responses to electrical nerve stimulation were upregulated (794%) by CH. CH ↑ dopa beta hydroxylase by 360% and SANX ablated this. CH↓ colocalization of a synthetic isoform of myosin heavy chain (SMemb) with smooth muscle alpha actin (AA) by 69%. SANX ↑ the colocalization by 600% in hypoxic arteries. NE in culture ↓ the colocalization by 91% and co‐culture of NE with prazosin ↑ it by 1363%. Also CH ↓ area per cell by 9% (media) and 45% (adventitia) whereas SANX ↑ it by 42% and 89% respectively. Also, CH ↓ colocalization of Ki67 (marker for cell proliferation) with AA by 15% (media) and 69% (adventitia). Together, these results suggest that the sympathetic cerebrovascular innervation helps mediate hypoxic remodeling through potentiation of NE synthesis, increased stimulation of α‐1 adrenoceptors, and transformation toward a contractile smooth muscle phenotype. Grant Funding Source : Supported by NIH Grants HD‐31266 and NS‐076945