RESUMEN
Traumatic brain injury (TBI) often presents with focal contusion and parenchymal bleeds, activating heme oxygenase (HO) to degrade released hemoglobin. Here we show that diffuse, midline fluid percussion injury causes time-dependent induction of HO-1 and iron binding proteins within both hemorrhagic neocortex and non-hemorrhagic hippocampus. Rats subjected to midline fluid percussion injury (FPI) survived 1-15d postinjury and tissue was collected for Western blot and immunohistochemical assays. HO-1 was elevated 1d after FPI, peaked at 3d, and returned to control baseline 7-15d. Iron management proteins lipocalin 2 (LCN2) and ferritin (FTL) exhibited distinct postinjury time courses, where peak LCN2 response preceded, and FTL followed that of HO-1. LCN2 elevation supported not only its role in iron transport, but also mediation of matrix metalloproteinase 9 (MMP9) activity. Upregulation of FTL for intracellular iron sequestration was delayed relative to both HO-1 and LCN2 induction. In the neocortex IBA-1+ microglia around the injury core expressed HO-1, but astrocytes co-localized with HO-1 in perilesional parenchyma. Non-hemorrhagic dentate gyrus showed predominant HO-1 labeling in hilar microglia and in molecular layer astrocytes. At 1d postinjury, LCN2 and HO-1 co-localized in a subpopulation of reactive glia within both brain regions. Notably, FTL was distributed within cells around injured vessels, damaged subcortical white matter, and along vessels of the hippocampal fissure. Together these results confirm that even the moderate, non-contusional insult of diffuse midline FPI can significantly activate postinjury HO-1 heme processing pathways and iron management proteins. Moreover, this activation is time-dependent and occurs in the absence of overt hemorrhage.
Asunto(s)
Lesiones Traumáticas del Encéfalo/metabolismo , Ferritinas/metabolismo , Hemo Oxigenasa (Desciclizante)/metabolismo , Lipocalina 2/metabolismo , Neocórtex/metabolismo , Animales , Astrocitos/metabolismo , Masculino , Metaloproteinasa 9 de la Matriz/metabolismo , Microglía/metabolismo , Neuronas/metabolismo , Ratas Sprague-DawleyRESUMEN
Olfactory receptor axons reinnervate the olfactory bulb (OB) after chemical or transection lesion. Diffuse brain injury damages the same axons, but the time course and regulators of OB reinnervation are unknown. Gelatinases (matrix metalloproteinase [MMP]2, MMP9) and their substrate osteopontin (OPN) are candidate mediators of synaptogenesis after central nervous system (CNS) insult, including olfactory axon damage. Here, we examined the time course of MMP9, OPN, and OPN receptor CD44 response to diffuse OB injury. FVBV/NJ mice received mild midline fluid percussion insult (mFPI), after which MMP9 activity and both OPN and CD44 protein expression were measured. Diffuse mFPI induced time-dependent increase in OB MMP9 activity and elevated the cell signaling 48-kD OPN fragment. This response was bimodal at 1 and 7 days post-injury. MMP9 activity was also correlated with 7-day reduction in a second 32-kD OPN peptide. CD44 increase peaked at 3 days, delayed relative to MMP9/OPN response. MMP9 and OPN immunohistochemistry suggested that deafferented tufted and mitral neurons were the principal sites for these molecular interactions. Analysis of injured MMP9 knockout (KO) mice showed that 48-kD OPN production was dependent on OB MMP9 activity, but with no KO effect on CD44 induction. Olfactory marker protein (OMP), used to identify injured olfactory axons, revealed persistent axon damage in the absence of MMP9. MMP9 KO ultrastructure at 21 days post-injury indicated that persistent OMP reduction was paired with delayed removal of degenerated axons. These results provide evidence that diffuse, concussive brain trauma induces a post-injury interaction between MMP9, OPN, and CD44, which mediates synaptic plasticity and reinnervation within the OB.
Asunto(s)
Conmoción Encefálica/metabolismo , Metaloproteinasa 9 de la Matriz/metabolismo , Plasticidad Neuronal/fisiología , Bulbo Olfatorio/patología , Osteopontina/metabolismo , Animales , Conmoción Encefálica/patología , Receptores de Hialuranos/metabolismo , Ratones , Ratones Noqueados , Neurogénesis/fisiología , Bulbo Olfatorio/metabolismo , Sinapsis/metabolismo , Sinapsis/patologíaRESUMEN
Despite the regenerative capacity of the olfactory bulb (OB), head trauma causes olfactory disturbances in up to 30% of patients. While models of olfactory nerve transection, olfactory receptor neuron (ORN) ablation, or direct OB impact have been used to examine OB recovery, these models are severe and not ideal for study of OB synaptic repair. We posited that a mild fluid percussion brain injury (mFPI), delivered over mid-dorsal cortex, would produce diffuse OB deafferentation without confounding pathology. Wild type FVB/NJ mice were subjected to mFPI and OB probed for ORN axon degeneration and onset of reactive synaptogenesis. OB extracts revealed 3â¯d postinjury elevation of calpain-cleaved 150-kDa αII-spectrin, an indicator of axon damage, in tandem with reduced olfactory marker protein (OMP), a protein specific to intact ORN axons. Moreover, mFPI also produced a 3-d peak in GFAP+ astrocyte and IBA1+ microglial reactivity, consistent with postinjury inflammation. OB glomeruli showed disorganized ORN axons, presynaptic degeneration, and glial phagocytosis at 3 and 7â¯d postinjury, all indicative of deafferentation. At 21â¯d after mFPI, normal synaptic structure re-emerged along with OMP recovery, supporting ORN afferent reinnervation. Robust 21â¯d postinjury upregulation of GAP-43 was consistent with the time course of ORN axon sprouting and synapse regeneration reported after more severe olfactory insult. Together, these findings define a cycle of synaptic degeneration and recovery at a site remote to non-contusive brain injury. We show that mFPI models diffuse ORN axon damage, useful for the study of time-dependent reactive synaptogenesis in the deafferented OB.
Asunto(s)
Axones/patología , Axones/fisiología , Conmoción Encefálica/patología , Conmoción Encefálica/fisiopatología , Bulbo Olfatorio/patología , Bulbo Olfatorio/fisiopatología , Animales , Astrocitos/patología , Astrocitos/fisiología , Modelos Animales de Enfermedad , Proteína GAP-43/metabolismo , Masculino , Ratones , Microglía/patología , Microglía/fisiología , Regeneración Nerviosa/fisiología , Plasticidad Neuronal/fisiología , Proteína Marcadora Olfativa/metabolismo , Neuronas Receptoras Olfatorias/patología , Neuronas Receptoras Olfatorias/fisiología , Distribución Aleatoria , Espectrina/metabolismo , Sinapsis/patología , Sinapsis/fisiología , Factores de TiempoRESUMEN
Valid and reliable animal models are essential for mechanistic and therapeutic studies of traumatic brain injury (TBI). Therefore, model characterization is a continual and reciprocal process between the experimental laboratory and the clinic. Several excellent experimental models of TBI, including the lateral fluid percussion rat model, are currently in wide use in many neurotrauma laboratories. However, small differences in the position of lateral fluid percussion craniectomy are reported between labs. Additionally, differences in hippocampal cell death have also been reported. Therefore, we hypothesized that small changes in craniectomy position could affect commonly used outcome measures such as vestibulomotor function, Morris water maze (MWM) performance, hippocampal cell loss, and glial fibrillary acidic protein (GFAP) immunoreactivity. Four placements were systematically manipulated: rostral, caudal, medial, and lateral. The medial and caudal placements produced significantly greater impairments in the MWM acquisition task over the lateral and rostral placements. The rostral placement produced diffuse cortical damage but little hippocampal cell loss. In contrast, the medial, lateral, and caudal placements produced more mid-dorsally localized cortical damage and significant cell loss in the CA2/CA3 and hilus ipsilateral to the injury site. Furthermore, reactive astrocytosis was more pronounced in the medial, lateral, and caudal placements than in the rostral placement. All craniectomy position groups had similar durations of traumatic unconsciousness and similar impairment on motor tasks. We conclude that small alterations in craniectomy position produce differences in cognitive performance, hippocampal cell loss, and reactive astrocytosis but not in motor performance nor transient unconsciousness.