Basic Science and Pathogenesis

Background: Cerebral microvascular dysfunction and nitro-oxidative stress are present in patients with Alzheimer's disease (AD) and may contribute to disease progression and severity. A pro-nitro-oxidative environment can lead to post-translational modifications of ion channels central to microvascular regulation in the brain, including the large conductance Ca²⁺-activated K⁺ channels (BK_Ca). Nitro-oxidative modulation of BK_Ca can resulting in decreased activity and vascular hyper-contractility, thus compromising neurovascular regulation. We hypothesized that nitro-oxidation of vascular BK_Ca function blunts micro- and neuro-vascular responses in 5x-FAD mice.

Methods: Six-months-old female 5x-FAD and wild-type (WT) littermates were used. Brain lysates were used to quantify BK_Ca nitro-oxidation. Cerebral arteries lysates were used to assess BK subunit expression by qPCR. A different set of cerebral arteries were used for patch clamp electrophysiology assessment of BK_Ca currents, ex vivo pressure myography and quantification of calcium (Ca²⁺) sparks in smooth muscle cells (SMC) by spinning-disk confocal microscopy. Basal cerebral perfusion and neurovascular coupling were assessed by laser speckle contrast imaging. Differences between means were tested using t-tests and considered statistically significant when P<0.05.

Results: We observed that BK_Ca S-nitrosylation, a proxy for nitro-oxidative modification, was increased in the brain of AD patients and in 5x-FAD females. In functional experiments, we observed that BK_Ca currents were lower in cerebral artery SMC of 5x-FAD than in WT. As a consequence, microvascular reactivity to BK_Ca blockade (iberiotoxin, 30 nM) was blunted in 5x-FAD, suggesting lower basal BK_Ca activity. This reduction in microvascular BK_Ca activity was independent of SMC Ca²⁺ sparks or BK_Ca mRNA expression. We then performed rescue experiments by incubating membrane patches and pressurized arteries with the reducing agent dithiothreitol (DTT, 10 µM), and observed that DTT restored BK_Ca currents and sensitivity to iberiotoxin in cerebral artery SMC from 5x-FAD. In vivo experiments showed that basal perfusion to the frontal cortex and neurovascular coupling were lower in 5x-FAD when compared to WT littermates.

Conclusion: These data suggest that excessive nitro-oxidation of BK_Ca mediates neuro- and micro-vascular impairments in female 5x-FAD mice, and that this process is reversible and can be rescued by reducing agents.

Funding: National Institutes on Aging and Alzheimer's Association.