Nitric oxide is not responsible for the initial sensory-induced neurovascular coupling response in mouse cortex

Abstract

AbstractNeurovascular coupling ensures that changes in neural activity are accompanied by localised changes in cerebral blood flow. While much is known about the involvement of excitatory neurons in neurovascular coupling, the role of inhibitory interneurons is unresolved. While nNOS-expressing interneurons have been shown to be capable of eliciting vasodilation, the role of nitric oxide in functional hyperemia remains a matter of debate. Therefore in the present study we applied a combination of optogenetic and pharmacological approaches, 2-dimensional optical imaging spectroscopy, and electrophysiology to investigate the role of nitric oxide in neurovascular coupling responses evoked by nNOS-expressing interneurons and whisker stimulation in mouse sensory cortex. The haemodynamic response evoked by nNOS-expressing interneurons was significantly altered in the presence of the NOS inhibitor LNAME, revealing a large initial 20-HETE-dependent vasoconstriction. In contrast, the haemodynamic response induced by sensory stimulation was largely unchanged by LNAME. Our results suggest that while nitric oxide plays a key role in neurovascular responses evoked by nNOS-expressing interneurons it does not mediate the initial sensory-induced neurovascular coupling response in mouse cortex. Thus, our results call into question the involvement of nNOS-expressing interneurons and nitric oxide in sensory-evoked functional hyperemia.