(A) A decrease in mitochondrial respiratory control ratio (RCR) in mitochondria isolated from CYP-rat L6-S1 spinal cords (SCs) as compared with control SCs (n = 3–5 per group). (B–F) Images were taken of the IBA-1–stained sections (×40 original magnification), and morphological characteristics were analyzed in lamina X (C) using Olympus cellSens software. (B) CYP significantly increased activation of rat L6-S1 SC microglia as compared with microglia from control rat L6-S1 SCs (n = 3–5 per group). (D–F) Representative images showing CYP-induced morphological changes in microglia from control (D), CYP (E), or 8-AG + CYP (F), whereby activation is exemplified by a retraction of cellular processes and an increase in cell body size. In all cases, 8-AG prevented CYP-induced mitochondrial (A) and morphological (B–F) changes such that mitochondrial RCR and microglia morphology were similar in 8-AG + CYP SCs versus control, healthy SCs. Insets are representative high-magnification images of a single microglial cell; note inset (E) depicts microglial activation (e.g., increased cell body size and retraction of processes) following CYP treatment. Scale bars: 20 μm and original magnification 60× (D–F); inset scale bars: 10 μm and original magnification 100×. (G) In cells isolated from neonatal brains, PNPase mRNA expression was highest in microglial cells (bar M, n = 3) compared with neurons (bar N, n = 3) or astrocytes (bar A, n = 3). (H) Inosine (substrate for PNPase) was metabolized to hypoxanthine in neurons, astrocytes, and microglia; however, isolated neonatal microglia exhibited the largest increase in hypoxanthine, which was reduced by the PNPase inhibitor 8-AG (n = 4 per group). Data are presented as means ± SD. Ordinary 1-way ANOVA followed by Tukey’s post hoc multiple-comparison test was used to evaluate significance; ****P < 0.00001.