Doug W. Smith

Changes in spinal GDNF, BDNF, and NT-3 expression after transient spinal cord ischemia in the rat

Previous studies have demonstrated that the expression of several growth factors including glial cell‐derived neurotrophic factor (GDNF), brain‐derived growth factor (BDNF), and neurotrophin‐3 (NT‐3) play an important role in defining neuronal survival after brain ischemia. In the present study, using a well‐defined model of transient spinal ischemia in rat, we characterized the changes in spinal GDNF, BDNF, and NT‐3 expression as defined by enzyme‐linked immunosorbent assay (ELISA) and immunofluorescence coupled with deconvolution microscopy. In control animals, baseline levels of GDNF, BDNF, and NT‐3 (74 ± 22, 3,600 ± 270, 593 ± 176 pg/g tissue, respectively) were measured. In the ischemic group, 6 min of spinal ischemia resulted in a biphasic response with increases in tissue GDNF and BDNF concentrations at the 2‐hr and 72‐hr points after ischemia. No significant differences in NT‐3 concentration were detected. Deconvolution analysis revealed that the initial increase in tissue GDNF concentration corresponded to a neuronal upregulation whereas the late peak seen at 72 hr corresponded with increased astrocyte‐derived GDNF synthesis. Increased expression of BDNF was seen in neurons, astrocytes, and oligodendrocytes. These data suggest that the early increase in neuronal GDNF/BDNF expression likely modulates neuronal resistance/recovery during the initial period of postischemic reflow. Increased astrocyte‐derived BDNF/GDNF expression corresponds with transient activation of astrocytes and may play an active role in neuronal plasticity after non‐injurious intervals of spinal ischemia.

c-Fos expression in hypothalamic neurosecretory and brainstem catecholamine cells following noxious somatic stimuli

Noxious somatic stimuli elicit vasopressin secretion, an effect thought to result from activation of a facilitatory input from A1 catecholamine cells of the medulla oblongata. To better characterize the A1 cell response and effects on other neuroendocrine A1 projection targets, particularly within the paraventricular nucleus, we have now mapped c-fos expression in neurochemically identified catecholamine and neurosecretory cells following a noxious somatic stimulus. Unilateral hind paw pinch significantly increased c-fos expression in contralateral A1 cells whereas other brainstem catecholamine cell groups were unaffected. Expression of c-fos was also increased in the supraoptic nucleus, this effect being more pronounced for vasopressin than oxytocin neurosecretory cells and, as with A1 cells, primarily on the side contralateral to the stimulated paw. In contrast, the increase in the paraventricular nucleus was greater in oxytocin rather than in vasopressin cells. Additionally there was a significant rise in c-fos expression in medial parvocellular paraventricular nucleus cells of noxiously stimulated animals. Notably, the majority of tuberoinfundibular corticotropin-releasing factor cells are located in this medial parvocellular zone. These results are consistent with and expand on those previously reported from electrophysiological and anatomical studies. The finding of differing neurosecretory cell responses between supraoptic and paraventricular nuclei has interesting implications with regard to the afferent control of neurosecretory cell activity. For example, the substantially greater activation of supraoptic versus paraventricular nucleus vasopressin cells, despite being innervated by the same medullary noradrenergic cell group, raises the possibility of a differential input or differences in responsiveness. Furthermore, the activation of paraventricular nucleus parvocellular cells is consistent with suggestions that the A1 cell group provides an excitatory input to this population.

Propensity to ‘relapse’ following exposure to cocaine cues is associated with the recruitment of specific thalamic and epithalamic nuclei

The thalamus is considered an important interface between the ventral striatopallidum and the dorsal striatum, and may therefore contribute to compulsive drug-seeking behaviour. Recent evidence suggests that the paraventricular thalamus (PVT), a dorsal midline thalamic nucleus, and the mediodorsal thalamus (MD) are involved in drug self-administration and respond to drug-associated cues. At present, however, the role of these thalamic regions in mediating cue-induced reinstatement of cocaine-seeking is unclear. Similarly, the habenula complex, part of the epithalamus, has been implicated in nicotine self-administration and cue-induced reinstatement of heroin seeking, but the role of this region in cocaine reinstatement behaviour has received little attention. Rats (n=20) were trained to self-administer cocaine in the presence of discriminative stimuli associated with drug availability (S⁺) or drug non-availability (S⁻). Once a stable level of responding was reached, lever pressing was extinguished. Animals were then tested for reinstatement and sacrificed immediately following the presentation of either the S⁻ or S⁺ discriminative stimuli, and Fos-protein expression was assessed in thalamic and epithalamic regions. Interestingly, significant variation was observed in reinstatement behaviour, allowing a comparison between high-reinstating (HR), low-reinstating (LR) and control animals. Compared with LR animals, HR animals exhibited increased Fos-protein expression in the PVT, intermediodorsal thalamus and the medial and lateral divisions of the habenula. Our data provide evidence that activation of thalamic and epithalamic nuclei is associated with propensity to reinstate to cocaine-seeking elicited by drug-related cues. We also build upon existing data highlighting the importance of the PVT in reinstatement behaviour.

Oxidative stress and dopamine deficiency in a genetic mouse model of Lesch-Nyhan disease.

Lesch-Nyhan disease, a neurogenetic disorder caused by congenital deficiency of the purine salvage enzyme hypoxanthine guanine phosphoribosyl transferase, is associated with a prominent loss of striatal dopamine. The current studies address the hypothesis that oxidant stress causes damage or dysfunction of nigrostriatal dopamine neurons in a knockout mouse model of the disease, by assessing several markers of oxidative damage and free radical scavenging systems. Some of these measures provided evidence for an increase in oxidative stress in the mutant mice (aconitase activity, oxidized glutathione, and lipid peroxides), but others did not (superoxide dismutase, protein thiol content, carbonyl protein content, total glutathione, glutathione peroxidase, catalase, and thiobarbituric reducing substances). Immunolocalization of heme-oxygenase 1 provided no evidence for oxidative stress restricted to specific elements of the striatum or midbrain in the mutants. Striatal dopamine systems of the mutant mice were more vulnerable to a challenge with the neurotoxin 6-hydroxydopamine, but they were not protected by cross-breeding the mutants with transgenic mice over-expressing superoxide dismutase. Overall, these data provide evidence for increased oxidative stress, but the failure to protect the knockout mice by over-expressing SOD1 argues that oxidative stress is not the sole process responsible for the loss of striatal dopamine.

Neurochemical identification of fos-positive neurons using two-colour immunoperoxidase staining

The discovery of immediate early genes (IEG) has provided neuroscientists with a new functional mapping technique. Labelling of neural tissue for the protein product of IEG provides an activity map with single-cell resolution. When combined with labelling for the chemical identity of the neuron, this provides a powerful tool for the investigation of specific cell populations along a neuraxis. Here we describe in detail a method which allows simultaneous bright-field visualization of neurochemically identified cells displaying increased IEG expression. This technique is evaluated in tissue from rats subjected to stimuli known to induce the expression of the IEG c-fos in various medullary catecholaminergic and hypothalamic neurosecretory cell groups. A 2-colour immunoperoxidase technique was used to visualize Fos, the nuclear protein product of c-fos, and the cytoplasmic antigens tyrosine hydroxylase (TH), phenylethanolamine N-methyl transferase (PNMT), oxytocin (OT) and vasopressin (VP). This involved simultaneous application of primary antibodies raised in different species followed by sequential application of appropriate biotinylated secondary antibodies and the avidin-biotin-peroxidase technique. Fos was visualized with nickel-intensified diaminobenzidine (Ni-DAB) in the first sequence while TH, PNMT, OT or VP were visualized with DAB alone, resulting in readily distinguishable black and amber reaction products, respectively. This dual immunoperoxidase technique is time saving compared to techniques using sequential application of primary antibodies and avoids the disadvantages associated with fluorescence techniques.

Mitochondrial DNA neutrophil extracellular traps are formed after trauma and subsequent surgery.

INTRODUCTION Neutrophil extracellular traps (NETs) have not been demonstrated after trauma and subsequent surgery. Neutrophil extracellular traps are formed from pure mitochondrial DNA (mtDNA) under certain conditions, which is potently proinflammatory. We hypothesized that injury and orthopedic trauma surgery would induce NET production with mtDNA as a structural component. METHODS Neutrophils were isolated 8 trauma patients requiring orthopedic surgery postinjury and up to 5 days postoperatively. Four healthy volunteers provided positive and negative controls. Total hip replacement patients acted as an uninjured surgical control group. Neutrophil extracellular traps were visualized with DNA (Hoechst 33342TM/Sytox Green/MitoSox/MitoTracker) stains using live cell fluorescence microscopy with downstream quantitative polymerase chain reaction analysis of DNA composition. RESULTS Neutrophil extracellular traps were present after injury in all 8 trauma patients. They persisted for 5 days postoperatively. Delayed surgery resulted in NET resolution, but they reformed postoperatively. Total hip replacement patients developed NETs postoperatively, which resolved by day 5. Quantitative polymerase chain reaction analysis of NET-DNA composition revealed that NETs formed after injury and surgery were made of mtDNA with no detectable nuclear DNA component. CONCLUSIONS Neutrophil extracellular traps formed after major trauma and subsequent surgery contain mtDNA and represent a novel marker of heightened innate immune activation. They could be considered when timing surgery after trauma to prevent systemic NET-induced inflammatory complications.

NTS catecholamine cell recruitment by hemorrhage and hypoxia

Immunolabelling for Fos and tyrosine hydroxylase was used to determine the patterns of activation of nucleus tractus solitarius catecholamine cells in response to graded levels of hemorrhage (0, 4, 8, 12 and 16 ml/kg) and systemic hypoxia (21, 14, 12, 10 and 8% O2) in conscious rats. Both stimuli elicited graded catecholamine cell recruitment with thresholds of 8 ml/kg and 12% O2. The majority of responsive neurons were A2 noradrenergic rather than C2 adrenergic cells. After hemorrhage most Fos-positive catecholamine cells were found below obex whereas most hypoxia-responsive cells were rostral to obex. These distinctive patterns of catecholamine cell recruitment may explain the differences in neuroendocrine responses to these stimuli.

Hypovolaemic and osmotic stimuli induce distinct patterns of c-Fos expression in the rat subfornical organ

Investigation of the effects of osmotic and hypovolaemic stimuli on the pattern of subfornical organ (SFO) c-fos expression yielded three distinct distributions of activated neurons. Hypertonic saline induced c-fos expression in peripheral SFO only. PEG/water induced c-fos in the central core of SFO and PEG/saline induced c-fos in both the central and peripheral regions. Isotonic saline failed to induce SFO c-fos expression. These results are consistent with the notion of functional segregation within the SFO.

Fluoxetine prevents development of an early stress-related molecular signature in the rat infralimbic medial prefrontal cortex. Implications for depression?

BackgroundPsychological stress, particularly in chronic form, can lead to mood and cognitive dysfunction and is a major risk factor in the development of depressive states. How stress affects the brain to cause psychopathologies is incompletely understood. We sought to characterise potential depression related mechanisms by analysing gene expression and molecular pathways in the infralimbic medial prefrontal cortex (ILmPFC), following a repeated psychological stress paradigm. The ILmPFC is thought to be involved in the processing of emotionally contextual information and in orchestrating the related autonomic responses, and it is one of the brain regions implicated in both stress responses and depression.ResultsGenome-wide microarray analysis of gene expression showed sub-chronic restraint stress resulted predominantly in a reduction in transcripts 24 hours after the last stress episode, with 239 genes significantly decreased, while just 24 genes had increased transcript abundance. Molecular pathway analysis using DAVID identified 8 pathways that were significantly enriched in the differentially expressed gene list, with genes belonging to the brain-derived neurotrophic factor – neurotrophin receptor tyrosine kinase 2 (BDNF-Ntrk2) pathway most enriched. Of the three intracellular signalling pathways that are downstream of Ntrk2, real-time quantitative PCR confirmed that only the PI3K-AKT-GSK3B and MAPK/ERK pathways were affected by sub-chronic stress, with the PLCγ pathway unaffected. Interestingly, chronic antidepressant treatment with the selective serotonin reuptake inhibitor, fluoxetine, prevented the stress-induced Ntrk2 and PI3K pathway changes, but it had no effect on the MAPK/ERK pathway.ConclusionsThese findings indicate that abnormal BDNF-Ntrk2 signalling may manifest at a relatively early time point, and is consistent with a molecular signature of depression developing well before depression-like behaviours occur. Targeting this pathway prophylactically, particularly in depression-susceptible individuals, may be of therapeutic benefit.

Exercise reverses the effects of early life stress on orexin cell reactivity in male but not female rats

Early life stress (ELS) is a known antecedent for the development of mood disorders such as depression. Orexin neurons drive arousal and motivated behaviors in response to stress. We tested the hypothesis that ELS alters orexin system function and leads to an altered stress-induced behavioral phenotype in adulthood. We also investigated if voluntary exercise during adolescent development could reverse the ELS-induced changes. Male and female Wistar rats were subjected to maternal separation stress on postnatal days (PND) 2-14. A subset of animals was given access to running wheels in late adolescence (1hr/day, PND40-70). In adulthood, rats were exposed to restraint stress and then tested on the open field (OF) and elevated plus maze (EPM). Brains were processed for Fos-protein and orexin or tyrosine hydroxylase immunohistochemistry. Restraint stress stimulated Fos-protein expression in perifornical area orexin cells, the paraventricular hypothalamic nucleus, and paraventricular thalamic nuclei, but this neuronal response was dampened in male and female rats exposed to ELS. ELS also reduced exploration in the OF, without affecting EPM behavior. These neural and behavioral changes are consistent with a depressive-like phenotype. Adolescent exercise reversed the orexin and behavioral deficits in ELS males. Exercise was not protective in females, although this may be due to sex differences in running behavior. Our findings highlight the inherent plasticity of the orexin system—a trait that may lead to a state of pathological rewiring but could also be treated using non-pharmacological approaches. We also highlight a need to better understand the sex-specific changes in orexin circuits and stress-related pathology.