Abstract
Genetic background is known to influence the outcome in mouse models of human disease, and previous experimental studies have shown strain variability in the neonatal mouse model of hypoxia–ischemia. To further map out this variability, we compared five commonly used mouse strains: C57BL/6, 129SVJ, BALB/c, CD1 and FVB in a pure hypoxic–ischemic setup and following pre-sensitization with lipopolysaccharide (LPS).Postnatal day 7 pups were subjected to unilateral carotid artery occlusion followed by continuous 30min 8% oxygen exposure at 36°C. Twelve hours prior, a third of the pups received a single intraperitoneal LPS (0.6μg/g) or a saline (vehicle) administration, respectively; a further third underwent hypoxia–ischemia alone without preceding injection. Both C57BL/6 and 129SVJ strains showed minimal response to 30min hypoxia–ischemia alone, BALB/c demonstrated a moderate response, and both CD1 and FVB revealed the highest brain damage. LPS pre-sensitization led to substantial increase in overall brain infarction, microglial and astrocyte response and cell death in four of the five strains, with exception of BALB/c that only showed a significant effect with terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL). Saline administration prior to hypoxia–ischemia resulted in an increase in inflammatory-associated markers, particularly in the astroglial activation of C57BL/6 mice, and in combined microglial activation and neuronal cell loss in FVB mice. Finally, two of the four strongly affected strains – C57BL/6 and CD1 – revealed pronounced contralateral astrogliosis with a neuroanatomical localization similar to that observed on the occluded hemisphere.Overall, the current findings demonstrate strain differences in response to hypoxia–ischemia alone, to stress associated with vehicle injection, and to LPS-mediated pre-sensitization, which partially explains the high variability seen in the neonatal mouse models of hypoxia–ischemia. These results can be useful in future studies of fetal/neonatal response to inflammation and reduced oxygen–blood supply.
Highlights
The postnatal day 7 mouse model of hypoxic–ischemic insult is widely used as a model of neuropathology that mimics, to a certain degree, the pathology of hypoxic– ischemic injury occurring in human late-preterm to term neonates (Sheldon et al, 1998; Clancy et al, 2001, 2007)
Hypoxia–ischemia is associated with a rapid increase in neural cell death- as shown in Fig. 3A; this is confirmed by transferase deoxyuridine triphosphate (dUTP) nick end labeling (TUNEL) histochemistry for nuclear fragmentation associated with hypoxia–ischemiainduced cell death at 48 h post-insult
TUNEL+ cell counts across the different individual brain regions revealed the highest increase in TUNEL+ cells in the isocortex of C57BL6 (p < 0.05), 129SVJ (p < 0.05) and FVB (p < 0.01) animals (Fig. 3D), hippocampus of C57BL/6 (p < 0.01), CD1 (p < 0.05) and FVB (p < 0.001) mice (Fig. 3H) and external capsule of C57BL/6 (p < 0.01), BALB/c (p < 0.05) and FVB (p < 0.05) pups (Fig. 3I)
Summary
The postnatal day 7 mouse model of hypoxic–ischemic insult is widely used as a model of neuropathology that mimics, to a certain degree, the pathology of hypoxic– ischemic injury occurring in human late-preterm to term neonates (Sheldon et al, 1998; Clancy et al, 2001, 2007). Previous research have shown that the strain background influences the degree of brain damage in neonatal mouse models of hypoxic (Li et al, 2008, 2009, 2013), ischemic (Comi et al, 2009) and hypoxic–ischemic (Sheldon et al, 1998) insults. To our knowledge, no study to date has investigated whether this strain-mediated variation in response to injury is seen in the synergistic model of inflammation and neonatal hypoxia–ischemia
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