Acute response of astrocytes under rose bengal photoinduction‐mediated vascular injury

Abstract Background Cerebrovascular pathology, often found in autopsy confirmed Alzheimer’s disease (AD), is widely believed to exacerbate AD pathophysiology and complicate anti‐AD treatment strategies. Perivascular cells such as astrocytes maintain the microenvironment for proper brain cell function and vascular integrity. Early occurrence of cerebral small vessel disease and astrocyte reactivity could lower the threshold of neuronal disorders and AD. Studies of astrocyte and microvascular pathology and function in the brain have been limited and reaction of astrocytes to vascular damage has yet to be fully understood. Method AAV‐Gfa‐EGFP or AAV‐Gfa‐GCaMP6 was injected into the barrel cortex of wild type mice followed by glass window installation. After 3 weeks recovery, rhodamine dextran was IV ‐injected and intravital brain imaging through two‐photon microscopy was performed at pre‐ and post‐photoinduction. Photoactivation of IV‐injected Rose Bengal dye (RB) technique was used to create vascular pathology. ImageJ was used for data analysis and GraphPad prism was used for statistical analysis. Result After photoinduction, green fluorescence intensity was increased in blood stream of both EGFP and GCaMP expressing brains. This result indicates a leakage of brain parenchyma component to blood stream. Astrocytic EGFP fluorescence intensity and astrocyte processes complexity were reduced after photoinduction in a time‐dependent manner. Interestingly, astrocyte calcium signaling was strikingly increased after photoinduction and returned back to the baseline at ∼1,000s post‐induction. The highest peak of astrocyte calcium signaling was located near a site of vascular damage, indicated by an increased in rhodamine fluorescence intensity in the brain parenchyma area. Astrocytic GCaMP intensity at the astrocyte endfeet surrounding small vasculature was increased, on the other hand, GCaMP intensity at the astrocyte processes are decreased in a time‐dependent manner. Consistently, we observed a reduction of vascular diameter after photoinduction in both EGFP and GCaMP expressing brains. Conclusion Acute vascular injury induced by rose bengal photoinduction altered astrocyte integrity and cellular signaling. This injury model resembles vascular constriction and hemorrhages found in human brain that could accelerate neurodegeneration and AD progression.