Kara McNair

Enhanced Hippocampal Long-Term Potentiation and Spatial Learning in Aged 11β-Hydroxysteroid Dehydrogenase Type 1 Knock-Out Mice

Glucocorticoids are pivotal in the maintenance of memory and cognitive functions as well as other essential physiological processes including energy metabolism, stress responses, and cell proliferation. Normal aging in both rodents and humans is often characterized by elevated glucocorticoid levels that correlate with hippocampus-dependent memory impairments. 11β-Hydroxysteroid dehydrogenase type 1 (11β-HSD1) amplifies local intracellular (“intracrine”) glucocorticoid action; in the brain it is highly expressed in the hippocampus. We investigated whether the impact of 11β-HSD1 deficiency in knock-out mice (congenic on C57BL/6J strain) on cognitive function with aging reflects direct CNS or indirect effects of altered peripheral insulin-glucose metabolism. Spatial learning and memory was enhanced in 12 month “middle-aged” and 24 month “aged” 11β-HSD1−/− mice compared with age-matched congenic controls. These effects were not caused by alterations in other cognitive (working memory in a spontaneous alternation task) or affective domains (anxiety-related behaviors), to changes in plasma corticosterone or glucose levels, or to altered age-related pathologies in 11β-HSD1−/− mice. Young 11β-HSD1−/− mice showed significantly increased newborn cell proliferation in the dentate gyrus, but this was not maintained into aging. Long-term potentiation was significantly enhanced in subfield CA1 of hippocampal slices from aged 11β-HSD1−/− mice. These data suggest that 11β-HSD1 deficiency enhances synaptic potentiation in the aged hippocampus and this may underlie the better maintenance of learning and memory with aging, which occurs in the absence of increased neurogenesis.

A Role for RhoB in Synaptic Plasticity and the Regulation of Neuronal Morphology

Actin-rich dendritic spines are the locus of excitatory synaptic transmission and plastic events such as long-term potentiation (LTP). Morphological plasticity of spines accompanies activity-dependent changes in synaptic strength. Several Rho GTPase family members are implicated in regulating neuronal and, in particular, spine structure via actin and the actin-binding protein cofilin. However, despite expression in hippocampus and cortex, its ability to modulate actin-regulatory proteins, and its induction during aging, RhoB has been relatively neglected. We previously demonstrated that LTP is associated with specific RhoB activation. Here, we further examined its role in synaptic function using mice with genetic deletion of the RhoB GTPase (RhoB−/− mice). Normal basal synaptic transmission accompanied reduced paired-pulse facilitation and post-tetanic potentiation in the hippocampus of RhoB−/− mice. Early phase LTP was significantly reduced in RhoB−/− animals, whereas the later phase was unaffected. In wild-type mice (RhoB+/+), Western blot analysis of potentiated hippocampus showed significant increases in phosphorylated cofilin relative to nonpotentiated slices, which were dramatically impaired in RhoB−/− slices. There was also a deficit in phosphorylated Lim kinase levels in the hippocampus from RhoB−/− mice. Morphological analysis suggested that lack of RhoB resulted in increased dendritic branching and decreased spine number. Furthermore, an increase in the proportion of stubby relative to thin spines was observed. Moreover, spines demonstrated increased length along with increased head and neck widths. These data implicate RhoB in cofilin regulation and dendritic and spine morphology, highlighting its importance in synaptic plasticity at a structural and functional level.

Restored plasticity in a mouse model of neurofibromatosis type 1 via inhibition of hyperactive ERK and CREB.

Patients with neurofibromatosis type 1 (NF1), resulting from neurofibromin gene mutations, frequently suffer from deficits in learning and spatial memory. Mice heterozygous for functional deletion of the NF1 gene (NF1+/– mice) also exhibit compromised spatial learning, and deficits in early‐stage hippocampal long‐term potentiation (LTP). Neurofibromin is a multifunctional protein which acts in part as an inhibitory constraint on Ras signalling, and the deficits in early‐stage LTP and spatial learning have been linked to Ras hyperactivation. However, the downstream targets of Ras hyperactivation that lead to cognitive disruption are unknown. The levels of activity of signalling molecules potentially downstream of Ras were therefore studied in NF1+/– mice. Elevated phospho‐ERK (pERK) levels were observed in the hippocampi from NF1+/– mice, while phospho‐Akt/PKB (pAkt) and phospho‐eIF4E (peIF4E) levels were unchanged relative to wild‐type mice. Hippocampal levels of phospho‐CREB (pCREB) were also increased, suggesting potential changes in late‐phase LTP in NF1+/– mice. Indeed, LTP was found to be impaired for at least 4 h following induction in NF1+/– mice, linking neurofibromin function with the long‐term maintenance of LTP. Remarkably, U0126, an inhibitor of ERK activation, at doses which reduced the hyperactive pERK levels in NF1+/– mice to the levels observed in control mice, caused a reduction in the deficits in early‐phase LTP and completely rescued the long‐term LTP deficits. In contrast to the abundant evidence that reductions in ERK activity lead to impaired plasticity, these data indicate that ERK hyperactivation in a partial model of type 1 neurofibromatosis leads to deficits in long‐lasting hippocampal plasticity.

Plasticity-related regulation of the hippocampal proteome

Plasticity of glutamatergic synapses is considered to be a pivotal mechanism underlying the ability of the CNS to reconfigure its neural circuits. A large number of studies have focused on investigating how individual proteins, biochemical pathways and structural processes alter both the induction and maintenance of synaptic plasticity. However, it is likely that synaptic plasticity involves temporally and spatially coordinated regulation of multiple protein complexes within the activated neural circuit. By using a global proteomics‐based approach we have now been able to reveal that highly diverse protein classes exhibit altered expression in response to both the activation of glutamate receptors and the induction of long‐term potentiation (LTP) of glutamatergic synaptic strength in the hippocampus; a brain area where plastic synaptic modification is believed to be key to cognitive processes, such as spatial learning. Of the 2946 resolvable protein spots detected in this study, 79 (2.7%) were significantly altered in abundance in response to 100 µm glutamate application (all P < 0.05). The majority (56 out of 79) of these changes were due to the activation of the N‐methyl‐d‐aspartate (NMDA) subtype of glutamate receptor. Likewise, the induction of LTP was associated with an altered abundance of 2.4% of the detectable proteome during the early (10 min) phase and 1.7% during the late (4 h) phase of its development. Observed changes in temporal and protein class‐specific patterns of expression depict a widespread shift from metabolic to structural protein alteration as the plasticity process matures.

Global changes in the hippocampal proteome following exposure to an enriched environment.

Exposure to an enriched environment promotes neurochemical, structural and neurophysiological changes in the brain and is associated with enhanced synaptic plasticity and improved hippocampal-dependent learning. Using a global proteomics-based approach we have now been able to reveal the altered expression of a diverse range of hippocampal proteins following exposure to an enriched environment. Male Hooded Lister rats (8 weeks) were subjected to a 6-week regimen in which they were housed in either non-enriched (open field) or enriched conditions (toys, wheels etc.). Whole protein extracts from stratum pyramidale and stratum radiatum of area CA1 were then isolated and subjected to differential gel electrophoresis [McNair K, Davies CH, Cobb SR (2006) Plasticity-related regulation of the hippocampal proteome. Eur J Neurosci 23(2):575-580]. Of the 2469 resolvable protein spots detected in this study, 42 spots (1.7% of the detectable proteome) derived from predominantly somatic fractions and 32 proteins spots from dendritic fractions (1.3% of detectable proteome) were significantly altered in abundance following exposure to an enriched environment (somatic: 14 increased/28 decreased abundance, range -1.5 to +1.4-fold change; dendritic: 16 increased, 16 decreased abundance, range -1.6 to +3.0-fold change). Following in-gel tryptic digestion and Maldi-Tof/Q-star mass spectrometry, database searching revealed the identity of 50 protein spots displaying environmental enrichment-related modulation of expression. Identified proteins belonged to a variety of functional classes with gene ontology analysis revealing the majority (>70%) of regulated proteins to be part of the energy metabolism, cytoplasmic organization/biogenesis and signal transduction processes.

Changes in synaptic transmission and protein expression in the brains of adult offspring after prenatal inhibition of the kynurenine pathway

During early brain development, N-methyl-d-aspartate (NMDA) receptors are involved in cell migration, neuritogenesis, axon guidance and synapse formation, but the mechanisms which regulate NMDA receptor density and function remain unclear. The kynurenine pathway of tryptophan metabolism includes an agonist (quinolinic acid) and an antagonist (kynurenic acid) at NMDA receptors and we have previously shown that inhibition of the pathway using the kynurenine-3-monoxygenase inhibitor Ro61-8048 in late gestation produces rapid changes in protein expression in the embryos and effects on synaptic transmission lasting until postnatal day 21 (P21). The present study sought to determine whether any of these effects are maintained into adulthood. After prenatal injections of Ro61-8048 the litter was allowed to develop to P60 when some offspring were euthanized and the brains removed for examination. Analysis of protein expression by Western blotting revealed significantly reduced expression of the GluN2A subunit (32%) and the morphogenetic protein sonic hedgehog (31%), with a 29% increase in the expression of doublecortin, a protein associated with neurogenesis. No changes were seen in mRNA abundance using quantitative real-time polymerase chain reaction. Neuronal excitability was normal in the CA1 region of hippocampal slices but paired-pulse stimulation revealed less inhibition at short interpulse intervals. The amount of long-term potentiation was decreased by 49% in treated pups and recovery after low-frequency stimulation was delayed. The results not only strengthen the view that basal, constitutive kynurenine metabolism is involved in normal brain development, but also show that changes induced prenatally can affect the brains of adult offspring and those changes are quite different from those seen previously at weaning (P21). Those changes may be mediated by altered expression of NMDAR subunits and sonic hedgehog.

Modified neocortical and cerebellar protein expression and morphology in adult rats following prenatal inhibition of the kynurenine pathway

Inhibition of the kynurenine pathway of tryptophan metabolism during gestation can lead to changes in synaptic transmission, neuronal morphology and plasticity in the rat hippocampus. This suggests a role for the kynurenine pathway in early brain development, probably caused by kynurenine modulation of N-methyl-d-aspartate (NMDA) glutamate receptors which are activated by the tryptophan metabolite quinolinic acid and blocked by kynurenic acid. We have now examined samples of neocortex and cerebellum of adult animals to assess the effects of a prenatally administered kynurenine-3-monoxygenase inhibitor (Ro61-8048) on protein and mRNA expression, dendritic structure and immuno-histochemistry. No changes were seen in mRNA expression using quantitative real-time polymerase chain reaction. Changes were detected in the expression of several proteins including the GluN2A subunit, unco-ordinated-5H3 (unc5H3), doublecortin, cyclo-oxygenase, sonic hedgehog and Disrupted in schizophrenia-1 (DISC1), although no differences in immunoreactive cell numbers were observed. In the midbrain, dependence receptor expression was also changed. The numbers and lengths of individual dendritic regions were not changed but there were significant increases in the overall complexity values of apical and basal dendritic trees. The data support the hypothesis that constitutive kynurenine metabolism plays a critical role in early, embryonic brain development, although fewer effects are produced in the neocortex and cerebellum than in the hippocampus and the nature of the changes seen are qualitatively different. The significant changes in DISC1 and unc5H3 may be relevant to cerebellar dysfunction and schizophrenia respectively, in which these proteins have been previously implicated.

Altered hippocampal plasticity by prenatal kynurenine administration, kynurenine-3-monoxygenase (KMO) deletion or galantamine

Highlights • Prenatal kynurenine or kynurenine monoxygenase deletion reduced adult hippocampal LTP.• There were no changes in expression of NMDA receptors or neurodevelopmental proteins.• The reduced LTP was reversed by galantamine which potentiates NMDAR activation.• Modifying kynurenine metabolism prenatally disturbs brain development in adulthood.

Altered apoptotic responses in neurons lacking RhoB GTPase

Caspase 3 activation has been linked to the acute neurotoxic effects of central nervous system damage, as in traumatic brain injury or cerebral ischaemia, and also to the early events leading to long‐term neurodegeneration, as in Alzheimer’s disease. However, the precise mechanisms activating caspase 3 in neuronal injury are unclear. RhoB is a member of the Rho GTPase family that is dramatically induced by cerebral ischaemia or neurotrauma, both in preclinical models and clinically. In the current study, we tested the hypothesis that RhoB might directly modulate caspase 3 activity and apoptotic or necrotic responses in neurons. Over‐expression of RhoB in the NG108‐15 neuronal cell line or in cultured corticohippocampal neurons elevated caspase 3 activity without inducing overt toxicity. Cultured corticohippocampal neurons from RhoB knockout mice did not show any differences in sensitivity to a necrotic stimulus – acute calcium ionophore exposure – compared with neurons from wild‐type mice. However, corticohippocampal neurons lacking RhoB exhibited a reduction in the degree of DNA fragmentation and caspase 3 activation induced by the apoptotic agent staurosporine, in parallel with increased neuronal survival. Staurosporine induction of caspase 9 activity was also suppressed. RhoB knockout mice showed reduced basal levels of caspase 3 activity in the adult brain. These data directly implicate neuronal RhoB in caspase 3 activation and the initial stages of programmed cell death, and suggest that RhoB may represent an attractive target for therapeutic intervention in conditions involving elevated caspase 3 activity in the central nervous system.