The preliminary inquiry confirms that subarachnoid hemorrhage (SAH) causes brain pericyte demise. Evaluating pericyte contractility post-SAH requires differentiation between viable and non-viable brain pericytes. Hence, a procedure has been developed to label viable and non-viable brain pericytes concurrently in brain sections, facilitating observation using a high-resolution confocal microscope.
Pericytes are crucial mural cells situated within cerebral microcirculation, pivotal in actively modulating cerebral blood flow via contractility adjustments. Conventionally, their contractility is gauged by observing morphological shifts and nearby capillary diameter changes under specific circumstances. Yet, post-tissue fixation, evaluating vitality and ensuing pericyte contractility of imaged brain pericytes becomes compromised. Similarly, genetically labeling brain pericytes falls short in distinguishing between viable and non-viable pericytes, particularly in neurologic conditions like subarachnoid hemorrhage (SAH), where our preliminary investigation validates brain pericyte demise. A reliable protocol has been devised to surmount these constraints, enabling simultaneous fluorescent tagging of both functional and non-functional brain pericytes in brain sections. This labeling method allows high-resolution confocal microscope visualization, concurrently marking the brain slice microvasculature. This innovative protocol offers a means to appraise brain pericyte contractility, its impact on capillary diameter, and pericyte structure. Investigating brain pericyte contractility within the SAH context yields insightful comprehension of its effects on cerebral microcirculation.
Brain pericytes, distinguished by their slender protuberances and protruding cell bodies, encircle the microcirculation1,2. While cerebral blood flow augmentation is predominantly driven by capillary dilation, smaller arteries exhibit slower rates of dilation3. Pericyte contractility exerts influence over capillary diameter and pericyte morphology, impacting vascular dynamics4. Contraction of brain pericytes leads to capillary constriction, and in pathological scenarios, excessive contraction may impede erythrocyte flow5. Various factors, including norepinephrine released from the locus coeruleus, can induce brain pericyte contraction within capillaries6. With a regulatory role in cerebral blood flow, pericytes exhibit 20-HETE synthesis, serving as an oxygen sensor during hyperoxia7. Oxidative-nitrative stress-triggered contraction of brain pericytes detrimentally affects capillaries5. Despite both in vivo and ex vivo investigations into brain pericyte contraction8, limited knowledge persists regarding the imaging of viable and non-viable brain pericytes within brain slices.
Crucially, post-tissue fixation imaging of brain pericytes compromises their vitality and subsequent contractility assessment. Moreover, in scenarios such as neurological disorders (e.g., subarachnoid hemorrhage – SAH), transgenic labeling of brain pericytes fails to differentiate between viable and non-viable pericytes, as confirmed by our preliminary SAH-induced brain pericyte death study9.
To surmount these challenges, we employed TO-PRO-3 to label live pericytes, while deceased ones were stained with propidium iodide (PI). We used high-resolution confocal imaging technologies to visualize viable and non-viable brain pericytes in brain slices while preserving slice activity during imaging. This article aims to present a reproducible method for imaging viable and non-viable brain pericytes in brain slices, serving as a valuable tool to probe the impact of brain pericytes on cerebral microcirculation post SAH.
The experimental protocol was approved by the Animal Ethics and Use Committee of Kunming Medical University (kmmu20220945). Sprague-Dawley (SD) rats of both sexes, 300-350 g, were used for the present study.
1. Inducing the SAH model
2. Brain slice preparation and stabilization
3. Labeling pericytes in acute brain slices with TO-PRO-3
NOTE: Pericytes from acute brain slices were fluorescently labeled using the tracer TO-PRO-310.
4. Staining non-vital pericytes of cerebral microcirculation in acute brain slices
5. Imaging of vital and non-vital brain pericytes in acute brain slices
Under normal physiological conditions, brain pericytes generally do not undergo cell death. Figure 6 illustrates this phenomenon, with yellow indicating the presence of vital brain pericytes; brain pericytes show no staining with PI, indicating their viability. To further investigate whether pericytes remain attached to the microvasculature following cell death, methods were employed in a SAH rat model, and subsequent imaging was conducted.
Methods for imaging both vital and non-vital brain pericytes in brain slices after SAH have been developed. As depicted in Figure 7, vital brain pericytes (blue arrows) are located within the microvasculature, while non-vital brain pericytes are represented by white arrows. This simultaneous visualization allows for the identification of both vital and non-vital brain pericytes within brain slices. Furthermore, it was observed that PI-labeled non-vital brain pericytes remained attached to the entire microvasculature.
Figure 1: SAH model. (A) The rat's head was firmly secured to the stereotaxic apparatus to ensure stability. The SAH model was induced by carefully inserting a stereotaxic needle into the suprasellar cistern. (B,C) In the SAH model, blood enters the subarachnoid space within the skull, affecting the brain. The cerebral hemispheres fill with blood approximately 24 h after SAH. Please click here to view a larger version of this figure.
Figure 2: Acute whole brain slice preparation. (A) The bottom chamber was coated with agarose glue for fixation. (B) The glue was meticulously applied to the bottom chamber to adhere firmly to the brain. (C) The surrounding tank was filled with ice-cold ACSF to maintain temperature. (D) The desired section thickness was carefully defined. (E,F). The brain slices were meticulously transferred to a 6-well plate. Please click here to view a larger version of this figure.
Figure 3: Transfer pipettes and dye-loading in a 6-well plate. (A) Acute brain slices were transferred using plastic Pasteur pipettes (3 mL). The length of the pipette used in (a) was 18.2 cm. For (b) and (c), the fine tip of the plastic Pasteur pipette was carefully trimmed to prevent any potential damage to the brain slices during transfer. The 6-well plates were efficiently transitioned from (B) to (C) for fluorescence staining in a 37 °C water bath. (B) One well of the 6-well plate accommodated a small nylon mesh strainer, with fine tubing positioned for gas delivery. Please click here to view a larger version of this figure.
Figure 4: Incubation of acute brain slices. A systematic procedure was meticulously followed to label pericytes with TO-PRO-3 in the acute brain slices. (A) Initially, one well of a six-well plate (12 × 8 cm) was filled with 10 mL of ACSF, ensuring proper aeration by bubbling the solution using fine tubing connected to a mixture of 95% O2 and 5% CO2. (B) Subsequently, the brain slices were meticulously transferred to the six-well plate. (C) 10 µL of the TO-PRO-3 stock solution was introduced into the dye-loading chamber, gently agitating to facilitate dye dissolution (D). (E,F) To further characterize the brain slices, staining with IB4 (1 µM in ACSF) and PI (1 µM in ACSF) was conducted. These sequential steps enabled the successful labeling of pericytes with TO-PRO-3 in acute brain slices, thus facilitating subsequent analysis and examination of the labeled brain pericytes. Please click here to view a larger version of this figure.
Figure 5: Imaging of vital and non-vital brain pericytes in brain slices. (A) The solution is equilibrated with a mixture of 95% O2 and 5% CO2 delivered through the tubing. (B–E) Setup for high-resolution imaging of TO-PRO-3-labeled, IB4-labeled endothelial, and PI-labeled cells in acute brain slices. (E) Confocal microscopy. Please click here to view a larger version of this figure.
Figure 6: Image of vital brain pericytes in brain slices. (A) Cerebral microvasculature was labeled with IB4 (green). (B) Non-vital cells were labeled with PI. (C) Vital pericytes were labeled with TO-PRO-3 (yellow). (D) The merged image is displayed. Please click here to view a larger version of this figure.
Figure 7: Representative image of vital and non-vital brain pericytes in a brain slice after SAH. (A) Cerebral microvasculature was labeled with IB4 (green). (B) Non-vital cells were labeled with PI (red). (C) Vital pericytes were labeled with TO-PRO-3 (yellow). (D) The merged image is displayed. Blue arrows indicate examples of vital brain pericytes, while white arrows indicate examples of non-vital brain pericytes. Notably, the nuclei of pericytes do not protrude above the microvascular surface. Please click here to view a larger version of this figure.
Figure 8: Positive correlation between the number of non-vital pericytes and time after SAH. High-resolution confocal imaging was employed to capture brain pericytes at various time points post SAH. Noticeable cell death of brain pericytes commenced at 6 h after SAH, as indicated by white arrows in (A). Subsequently, there was a substantial increase in pericyte death from the 6 h mark onward. The count of non-vital pericytes displayed a positive correlation with the time elapsed after SAH, as depicted in (B). Please click here to view a larger version of this figure.
Developed are high-resolution confocal imaging techniques for visualizing vital brain pericytes, non-vital brain pericytes, and the microvasculature in brain slices. In acute rat brain slices, the process entails initial labeling of pericytes with TO-PRO-311, followed by microvascular endothelial cells with IB412; subsequently, identification of deceased pericytes is conducted using PI. This protocol is straightforward, reproducible, and highly applicable for functional research.
To specifically trace brain pericytes within the nervous system, the far-red fluorophore TO-PRO-3 is employed. While TO-PRO-3 predominantly stains the nuclei of fixed tissue13, it selectively incorporates into living pericytes ex vivo when applied in physiological saline14. Prior studies have affirmed the unequivocal identification of murine brain pericytes using TO-PRO-315. This fluorophore effectively labels vital brain pericytes11. In contrast, PI, a commonly utilized charged fluorochrome for real-time cell viability assessment12, serves as a marker for deteriorating cells when applied before fixation (pre-fixation PI staining)16. However, since the morphological characteristics of pericytes, particularly their nuclei, do not extend above the microvascular surface, distinguishing between endothelial and pericyte nuclei using PI staining can be challenging, as indicated by the white arrow in Figure 8A. Studies involving electron microscopy for three-dimensional reconstruction of the CA1 region of the rat hippocampus have suggested that approximately one-third of the endothelium is covered by the somas and processes of pericytes17.
In Figure 6, brain pericytes labeled with TO-PRO-3 are observed within the microvasculature. Confocal images of the cerebral microvasculature labeled with IB4 and PI reveal that only a few cells undergo cell death during the sectioning process, as evidenced by the absence of PI-positive dead cells in Figure 6. Consequently, the SAH model is utilized to investigate the presence of non-vital pericytes. Figure 7 illustrates that, within brain slices, cell death is more prominent in pericytes compared to endothelial cells. Additionally, in Figure 8A, a significant increase in pericyte death is observed starting 6 h after SAH. Figure 8B demonstrates a positive correlation between the number of non-vital pericytes and the time elapsed after SAH. Nevertheless, a comprehensive study imaging both vital and non-vital brain pericytes have not been documented to the best of the current knowledge.
Currently, it remains uncertain whether pericytes from other species or systems (e.g., heart, small intestine) also manifest vital and non-vital states in acute slices after SAH. In conclusion, the provided protocol offers a replicable approach for imaging both vital and non-vital brain pericytes in brain slices post-SAH. Due to its simplicity and reliability, this technique can be employed to unveil the functional and structural diversity of pericytes in brain slices and facilitate detailed cellular investigations in various disease models related to pericyte pathophysiology.
The authors have nothing to disclose.
The study was supported by grants from the National Natural Science Foundation of China (81960226,81760223); the Natural Science Foundation of Yunnan Province (202001AS070045,202301AY070001-011)
6-well plate | ABC biochemistry | ABC703006 | RT |
Adobe Photoshop | Adobe | Adobe Illustrator CS6 16.0.0 | RT |
Aluminium foil | MIAOJIE | 225 mm x 273 mm | RT |
CaCl2·2H2O | Sigma-Aldrich | C3881 | RT |
Confocal imaging software | Nikon | NIS-Elements 4.10.00 | RT |
Confocal Laser Scanning Microscope | Nikon | N-SIM/C2si | RT |
Gas tank (5% CO2, 95% O2) | PENGYIDA | 40L | RT |
Glass Bottom Confocal Dishes | Beyotime | FCFC020-10pcs | RT |
Glucose | Sigma-Aldrich | G5767 | RT |
Glue | EVOBOND | KH-502 | RT |
Ice machine | XUEKE | IMS-20 | RT |
Image analysis software | National Institutes of Health (NIH) | Image J | RT |
Inhalation anesthesia system | SCIENCE | QAF700 | RT |
Isolectin B 4-FITC | SIGMA | L2895–2MG | Store aliquots at –20 °C |
KCl | Sigma-Aldrich | 7447–40–7 | RT |
KH2PO4 | Sigma-Aldrich | P0662 | RT |
MgSO4 | Sigma-Aldrich | M7506 | RT |
NaCl | Sigma-Aldrich | 7647–14–5 | RT |
NaH2PO4·H2O | Sigma-Aldrich | 10049–21–5 | RT |
NaHCO3 | Sigma-Aldrich | S5761 | RT |
Pasteur pipette | NEST Biotechnology | 318314 | RT |
Peristaltic Pump | Scientific Industries Inc | Model 203 | RT |
Propidium (Iodide) | Med Chem Express | HY-D0815/CS-7538 | Store aliquots at –20 °C |
Stereotaxic apparatus | SCIENCE | QA | RT |
Syringe pump | Harvard PUMP | PUMP 11 ELITE Nanomite | RT |
Thermostatic water bath | OLABO | HH-2 | RT |
Vibrating microtome | Leica | VT1200 | RT |