Smoking Progression and Nicotine-Enhanced Reward Sensitivity Predicted by Resting-State Functional Connectivity in Salience and Executive Control Networks.

INTRODUCTION: The neural underpinnings underlying individual differences in nicotine-enhanced reward sensitivity (NERS) and smoking progression are poorly understood. Thus, we investigated whether brain resting-state functional connectivity (rsFC.) during smoking abstinence predicts NERS and smoking progression in young light smokers. We hypothesized that high rsFC between brain areas with high densities of nicotinic receptors (insula, anterior cingulate cortex [ACC], hippocampus, thalamus) and areas involved in reward-seeking (nucleus accumbens [NAcc], prefrontal cortex [PFC]) would predict NERS and smoking progression. AIMS AND METHODS: Young light smokers (N = 64, age 18-24, M = 1.89 cigarettes/day) participated in the study. These individuals smoked between 5 and 35 cigarettes per week and lifetime use never exceeded 35 cigarettes per week. Their rsFC was assessed using functional magnetic resonance imaging after 14 hours of nicotine deprivation. Subjects also completed a probabilistic reward task after smoking a placebo on 1 day and a regular cigarette on another day. RESULTS: The probabilistic-reward-task assessed greater NERS was associated with greater rsFC between the right anterior PFC and right NAcc, but with reduced rsFC between the ACC and left inferior prefrontal gyrus and the insula and ACC. Decreased rsFC within the salience network (ACC and insula) predicted increased smoking progression across 18 months and greater NERS. CONCLUSIONS: These findings provide the first evidence that differences in rsFCs in young light smokers are associated with nicotine-enhanced reward sensitivity and smoking progression. CLINICAL TRIAL REGISTRATION: NCT02129387 (preregistered hypothesis: www.clinicaltrials.gov). IMPLICATIONS: Weaker rsFC within the salience network predicted greater NERS and smoking progression. These findings suggest that salience network rsFC and drug-enhanced reward sensitivity may be useful tools and potential endophenotypes for reward sensitivity and drug-dependence research.

Symbol relations training improves cognitive functioning in students with neurodevelopmental disorders.

Students with neurodevelopmental disorders [Specific Learning Disorders (SLD), Attention Deficit Hyperactivity Disorder (ADHD), Autism Spectrum Disorder (ASD)] often experience learning challenges due to underlying weaknesses in cognitive processes. As these are some of the most common conditions to impact functioning, the development of effective treatments is a priority for neuropsychologists. However, the task of designing effective cognitive interventions has proven one of the most difficult challenges for our field. The Arrowsmith Program uses a novel approach compared to other cognitive intervention programs. We hypothesized that intensive practice of one aspect of this program would lead to improved cognitive functions in students with neurodevelopmental disorders. Twenty-seven students with neurodevelopmental disorders (ages 9.4-18.4 years) were recruited from Arrowsmith schools. Cognitive baseline and post-intervention data were gathered using components of the Woodcock-Johnson IV Tests of Cognitive Abilities. The intervention consisted of 6 weeks of intensive practice of the Symbol Relations Task. W-scores were used in a paired sample t-test analysis to determine if cognitive skill improvement occurred. Significant improvements were found in several measures of neuropsychological assessment, in particular in the Cattell-Horn-Carroll broad abilities These results provide a foundation for further work examining the utility of this novel approach to cognitive intervention.

APOE genotype influences P3b amplitude and response to smoking abstinence in young adults.

RATIONALE: There is strong evidence that nicotine can enhance cognitive functions and growing evidence that this effect may be larger in young healthy APOE ε4 carriers. However, the moderating effects of the APOE ε4 allele on cognitive impairments caused by nicotine deprivation in chronic smokers have not yet been studied with brain indices. OBJECTIVE: We sought to determine whether young female carriers of the APOE ε4 allele, relative to noncarriers, would exhibit larger abstinence-induced decreases in P3b amplitude during a two-stimulus auditory oddball task. METHODS: We compared parietal P3bs in female chronic smokers with either APOE ε3/ε3 (n = 54) or ε3/ε4 (n = 20) genotype under nicotine-sated conditions and after 12-17-h nicotine deprivation. RESULTS: Nicotine deprivation significantly reduced P3b amplitudes in APOE ε4 carriers, but not in APOE-ε3/ε3 individuals, such that the difference seen prior to nicotine deprivation was eliminated. CONCLUSIONS: The results suggest that subjects with the APOE ε4 allele are more sensitive to nicotine, which could influence smoking patterns, the risk for nicotine dependence, and the cognitive effects of nicotine use in these individuals.

Impaired memory and marble burying activity in deformed epidermal autoregulatory factor 1 (Deaf1) conditional knockout mice.

Deleterious mutations within the DNA binding domain of the transcription factor deformed epidermal autoregulatory factor 1 (DEAF1) result in a phenotypic spectrum of neurodevelopmental disorders including intellectual disabilities and autism spectrum disorders. While whole animal deletion of Deaf1 in mice is lethal, mice with conditional disruption of the gene in neuronal precursor cells can display memory deficits and increased anxiety-like behavior. This study aimed to further characterize learning and memory alterations and assess changes in marble burying activity and hippocampal size in mice with conditional deletion of Deaf1. Mice lacking DEAF1 in the CNS (NKO) displayed reduced memory in both contextual fear conditioning and a 3-day massed trials Morris water maze paradigm. NKO mice had reduced marble burying activity in full cage marble burying tests. Using a half-cage marble test, NKO mice again buried fewer marbles and spent significantly more time on the side of the cage away from the marbles compared to control animals. The area of the dorsal hippocampus of NKO mice was decreased compared to control and animals with a single Deaf1 allele. These results continue to establish the importance of DEAF1 in cognitive behavior and provide new evidence that DEAF1 regulates hippocampal morphology.

Butein attenuates the cytotoxic effects of LPS-stimulated microglia on the SH-SY5Y neuronal cell line.

Neuroinflammation is involved in brain aging and neuronal cell death in neurodegenerative diseases such as Alzheimer's disease (AD). Butein has been suggested to have anti-inflammatory, anti-apoptotic, and anti-cancer effects. However, few studies have been done to evaluate whether butein exerts protective effects on neurons, and the potential mechanism for this effect has not been studied. Here, we examined the effect of butein on SH-SY5Y neuroblastoma cells grown with conditioned medium from BV2 microglia cells that had been activated by lipopolysaccharide (LPS) as a neuroinflammation model. We found butein pretreatment significantly increased SH-SY5Y cell viability in a dose-dependent manner by inhibiting the apoptosis normally induced by microglia-conditioned medium. SH-SY5Y cells treated with microglia-conditioned medium showed upregulated ERK signaling pathway-related mRNA expression and protein phosphorylation, which was dose-dependently reversed by butein. Immunocytochemistry and Western blot results showed that BV2-LPS conditioned medium-induced Nuclear factor kappaB (NF-κB) transactivational activity in SH-SY5Y cells, but this was attenuated by butein treatment of the BV2 cells prior to their exposure to LPS. Collectively, our results indicate that butein effectively mitigates inflammatory injury caused by LPS-conditioned medium from microglia, possibly due to reductions in the transactivational activity of NF-κB p65 and ERK signaling pathway activation, and provide evidence for a neuroprotective role of butein through blocking negative consequences of microglial activation.

Impaired Glucose Tolerance and Reduced Plasma Insulin Precede Decreased AKT Phosphorylation and GLUT3 Translocation in the Hippocampus of Old 3xTg-AD Mice.

Several studies have demonstrated that mouse models of Alzheimer's disease (AD) can exhibit impaired peripheral glucose tolerance. Further, in the APP/PS1 mouse model, this is observed prior to the appearance of AD-related neuropathology (e.g., amyloid-ß plaques; Aß) or cognitive impairment. In the current study, we examined whether impaired glucose tolerance also preceded AD-like changes in the triple transgenic model of AD (3xTg-AD). Glucose tolerance testing (GTT), insulin ELISAs, and insulin tolerance testing (ITT) were performed at ages prior to (1-3 months and 6-8 months old) and post-pathology (16-18 months old). Additionally, we examined for altered insulin signaling in the hippocampus. Western blots were used to evaluate the two-primary insulin signaling pathways: PI3K/AKT and MAPK/ERK. Since the PI3K/AKT pathway affects several downstream targets associated with metabolism (e.g., GSK3, glucose transporters), western blots were used to examine possible alterations in the expression, translocation, or activation of these targets. We found that 3xTg-AD mice display impaired glucose tolerance as early as 1 month of age, concomitant with a decrease in plasma insulin levels well prior to the detection of plaques (∼14 months old), aggregates of hyperphosphorylated tau (∼18 months old), and cognitive decline (≥18 months old). These alterations in peripheral metabolism were seen at all time points examined. In comparison, PI3K/AKT, but not MAPK/ERK, signaling was altered in the hippocampus only in 18-20-month-old 3xTg-AD mice, a time point at which there was a reduction in GLUT3 translocation to the plasma membrane. Taken together, our results provide further evidence that disruptions in energy metabolism may represent a foundational step in the development of AD.

Evidence for altered insulin receptor signaling in Alzheimer's disease.

Epidemiological data have shown that metabolic disease can increase the propensity for developing cognitive decline and dementia, particularly Alzheimer's disease (AD). While this interaction is not completely understood, clinical studies suggest that both hyper- and hypoinsulinemia are associated with an increased risk for developing AD. Indeed, insulin signaling is altered in post-mortem brain tissue from AD patients and treatments known to enhance insulin signaling can improve cognitive function. Further, clinical evidence has shown that AD patients and mouse models of AD often display alterations in peripheral metabolism. Since insulin is primarily derived from the periphery, it is likely that changes in peripheral insulin levels lead to alterations in central nervous system (CNS) insulin signaling and could contribute to cognitive decline and pathogenesis. Developing a better understanding of the relationship between alterations in peripheral metabolism and cognitive function might provide a foundation for the development of better treatment options for patients with AD. In this article we will begin to piece together the present data defining this relationship by briefly discussing insulin signaling in the periphery and CNS, its role in cognitive function, insulin's relationship to AD, peripheral metabolic alterations in mouse models of AD and how information from these models helps understand the mechanisms through which these changes potentially lead to impairments in insulin signaling in the CNS, and potential ways to target insulin signaling that could improve cognitive function in AD. This article is part of the Special Issue entitled 'Metabolic Impairment as Risk Factors for Neurodegenerative Disorders.'

Experimentally induced diabetes worsens neuropathology, but not learning and memory, in middle aged 3xTg mice.

Alzheimer's disease (AD) is the primary cause of dementia in the elderly. The cause of the disease is still unknown, but amyloid plaques and neurofibrillary tangles in the brain are thought to play a role. However, transgenic mouse models expressing these neuropathological features do not show severe or consistent cognitive impairments. There is accumulating evidence that diabetes increases the risk for developing AD. We tested the hypothesis that experimentally induced diabetes would exacerbate cognitive symptoms in a mouse model of AD. Diabetes was induced in 12-month old 3xTg mice using streptozotocin (STZ; 90mg/kg, i.p., on two successive days). Hyperglycemia was verified by sampling blood glucose levels. Three months after injection (at 15 months of age), the mice were behaviorally tested in the Morris water maze and contextual fear conditioning. Subsequently, the hippocampal region was examined using immunohistochemistry (6E10 antibody for amyloid) and immunoblotting (AT8 antibody for phosphorylated tau). No differences were found in learning or memory between the vehicle-treated control and STZ-treated groups. A significant increase in the number of amyloid-positive plaques was observed in the subiculum of STZ-treated mice; very few plaques were seen in other hippocampal regions in either group. No differences in AT8 load were observed. These results reinforce that amyloid plaques, per se, are not sufficient to cause memory impairments. Further, while diabetes can enhance this aspect of brain pathology, the combination of disrupted glucose metabolism and the transgenes is still not sufficient to cause the severe cognitive impairments associated with clinical AD.

Glucose tolerance and insulin sensitivity are impaired in APP/PS1 transgenic mice prior to amyloid plaque pathogenesis and cognitive decline.

Alzheimer's disease (AD) is a progressive neurodegenerative disease characterized by beta-amyloid (Aß) deposition, neurofibrillary tangles and cognitive decline. Clinical data suggests that both type 1 and type 2 diabetes are risk factors for AD-related dementia and several clinical studies have demonstrated that AD patients show alterations in peripheral glucose regulation characterized by insulin resistance (hyperinsulinemia) or hypoinsulinemia. Whether animal models of AD exhibit a pre-diabetic phenotype without additional dietary or experimental manipulation is unclear however, with contradictory data available. Further, most studies have not examined the time course of potential pre-diabetic changes relative to AD pathogenesis and cognitive decline. Thus, in this study we tested the hypothesis that a pre-diabetic phenotype (peripheral metabolic dysregulation) exists in the APP/PS1 transgenic model of AD under normal conditions and precedes AD-related pathology. Specifically, we examined glucose tolerance in male APP/PS1 mice on a C57BL/6J congenic background at 2, 4-6 and 8-9months of age by assessing fasting glucose levels, glucose tolerance, plasma insulin levels and insulin sensitivity as well as the development of pathological characteristics of AD and verified that our APP/PS1 mice develop cognitive impairment. Here we show that APP/PS1 mice, compared to wild-type controls, exhibit a significant impairment in glucose tolerance during an intraperitoneal glucose tolerance test (ipGTT) and a trend for increased fasting plasma insulin concentrations as early as 2months of age, while extracellular Aß1-42 deposition occurs later and cognitive decline exists at 8-9months of age. Moreover, APP/PS1 mice did not respond as well to exogenous insulin as the wild-type controls during an intraperitoneal insulin tolerance test (ipITT). Taken together, these data reveal that male APP/PS1 mice on a C57BL/6J congenic background exhibit a pre-diabetic phenotype prior to the development of AD-like pathology and that this metabolic deficit persists when they exhibit neuropathology and cognitive decline. This raises the question of whether altered glucose regulation and insulin production/secretion could contribute to AD pathogenesis.

Sex Differences in Long-Term Potentiation at Temporoammonic-CA1 Synapses: Potential Implications for Memory Consolidation.

Sex differences in spatial memory have long been observed in humans, non-human primates and rodents, but the underlying cellular and molecular mechanisms responsible for these differences remain obscure. In the present study we found that adolescent male rats outperformed female rats in 7 d and 28 d retention probes, but not in learning trials and immediate probes, in the Morris water maze task. Male rats also had larger long-term potentiation (LTP) at hippocampal temproammonic-CA1 (TA-CA1) synapses, which have been implicated to play a key role in place field and memory consolidation, when protocols designed to elicit late-stage LTP (LLTP) were used. Interestingly, the ratio of evoked AMPA/NMDA currents was found to be smaller at TA-CA1 synapses in male rats compared to female rats. Protein biotinylation experiments showed that male rats expressed more surface GluN1 receptors in hippocampal CA1 stratum lacunosum-moleculare (SLM) than female rats, although GluA1 expression was also slightly higher in male rats. Taken together, our results suggest that differences in the expression of AMPA and NMDA receptors may affect LTP expression at TA-CA1 synapses in adolescent male and female rats, and thus possibly contribute to the observed sex difference in spatial memory.

The essential role of hippocampal alpha6 subunit-containing GABAA receptors in maternal separation stress-induced adolescent depressive behaviors.

Exposure to early stressful adverse life events such as maternal separation severely impacts the development of the nervous system. Using immunohistochemistry, quantitative PCR and Western blot approaches, we found that alpha6 subunit-containing GABAA receptors (Gabra6-containing GABAA Rs) were expressed on hippocampal interneurons of adolescent rats. Maternal separation stress (MS) from postnatal day 2 to15 significantly reduced Gabra6 expression and provoked depressive behaviors such as anhedonia. Furosemide, the selective antagonist of Gabra6-containing GABAARs, strongly increased peak amplitude of evoked IPSCs at CA3-CA1 synapses and the frequency of miniature IPSPs recorded from CA1 pyramidal cells in naive control animals, and this effect was occluded in MS animals. Knockdown of Gabra6 expression in hippocampus mimicked furosemide's effect and was sufficient to produce similar depressive symptoms that were observed in MS animals. These results indicate that the Gabra6-containing GABAA R is a key modulator of hippocampal synaptic transmission and likely plays a crucial role in the pathophysiology of maternal separation-induced depression.

Mutations affecting the SAND domain of DEAF1 cause intellectual disability with severe speech impairment and behavioral problems.

Recently, we identified in two individuals with intellectual disability (ID) different de novo mutations in DEAF1, which encodes a transcription factor with an important role in embryonic development. To ascertain whether these mutations in DEAF1 are causative for the ID phenotype, we performed targeted resequencing of DEAF1 in an additional cohort of over 2,300 individuals with unexplained ID and identified two additional individuals with de novo mutations in this gene. All four individuals had severe ID with severely affected speech development, and three showed severe behavioral problems. DEAF1 is highly expressed in the CNS, especially during early embryonic development. All four mutations were missense mutations affecting the SAND domain of DEAF1. Altered DEAF1 harboring any of the four amino acid changes showed impaired transcriptional regulation of the DEAF1 promoter. Moreover, behavioral studies in mice with a conditional knockout of Deaf1 in the brain showed memory deficits and increased anxiety-like behavior. Our results demonstrate that mutations in DEAF1 cause ID and behavioral problems, most likely as a result of impaired transcriptional regulation by DEAF1.

Altered network timing in the CA3-CA1 circuit of hippocampal slices from aged mice.

Network patterns are believed to provide unique temporal contexts for coordinating neuronal activity within and across different regions of the brain. Some of the characteristics of network patterns modeled in vitro are altered in the CA3 or CA1 subregions of hippocampal slices from aged mice. CA3-CA1 network interactions have not been examined previously. We used slices from aged and adult mice to model spontaneous sharp wave ripples and carbachol-induced gamma oscillations, and compared measures of CA3-CA1 network timing between age groups. Coherent sharp wave ripples and gamma oscillations were evident in the CA3-CA1 circuit in both age groups, but the relative timing of activity in CA1 stratum pyramidale was delayed in the aged. In another sample of aged slices, evoked Schaffer collateral responses were attenuated in CA3 (antidromic spike amplitude) and CA1 (orthodromic field EPSP slope). However, the amplitude and timing of spontaneous sharp waves recorded in CA1 stratum radiatum were similar to adults. In both age groups unit activity recorded juxtacellularly from unidentified neurons in CA1 stratum pyramidale and stratum oriens was temporally modulated by CA3 ripples. However, aged neurons exhibited reduced spike probability during the early cycles of the CA3 ripple oscillation. These findings suggest that aging disrupts the coordination of patterned activity in the CA3-CA1 circuit.

γ-secretase binding sites in aged and Alzheimer's disease human cerebrum: the choroid plexus as a putative origin of CSF Aß.

Deposition of ß -amyloid (Aß) peptides, cleavage products of ß-amyloid precursor protein (APP) by ß-secretase-1 (BACE1) and γ-secretase, is a neuropathological hallmark of Alzheimer's disease (AD). γ-Secretase inhibition is a therapeutical anti-Aß approach, although changes in the enzyme's activity in AD brain are unclear. Cerebrospinal fluid (CSF) Aß peptides are thought to derive from brain parenchyma and thus may serve as biomarkers for assessing cerebral amyloidosis and anti-Aß efficacy. The present study compared active γ-secretase binding sites with Aß deposition in aged and AD human cerebrum, and explored the possibility of Aß production and secretion by the choroid plexus (CP). The specific binding density of [(3) H]-L-685,458, a radiolabeled high-affinity γ-secretase inhibitor, in the temporal neocortex and hippocampal formation was similar for AD and control cases with similar ages and post-mortem delays. The CP in post-mortem samples exhibited exceptionally high [(3) H]-L-685,458 binding density, with the estimated maximal binding sites (Bmax) reduced in the AD relative to control groups. Surgically resected human CP exhibited APP, BACE1 and presenilin-1 immunoreactivity, and ß-site APP cleavage enzymatic activity. In primary culture, human CP cells also expressed these amyloidogenic proteins and released Aß40 and Aß42 into the medium. Overall, our results suggest that γ-secretase activity appears unaltered in the cerebrum in AD and is not correlated with regional amyloid plaque pathology. The CP appears to be a previously unrecognised non-neuronal contributor to CSF Aß, probably at reduced levels in AD.

Water maze testing to identify compounds for cognitive enhancement.

The water maze task is widely used to evaluate spatial learning and memory in rodents. The basic paradigm requires an animal to swim in a pool until it finds a hidden escape platform. The animals learn to find the platform using extra-maze cues and, after several training trials, are able to swim directly to it from any starting location. Memory for the platform location is assessed by examining swimming behavior with the platform removed from the maze, while sensory, motor and motivational aspects of the task can be examined by making the platform visible to the animals. Described in this unit is the use of the water maze to identify rats with age-related spatial learning and memory impairments. The efficacy of potential pharmacological treatments for alleviating these deficits is then evaluated. This assay provides a means for studying the neurobiology of spatial learning and memory, and to identify potential pharmacotherapies for treating memory-impaired humans. While the use of aged rats is described in this unit, the protocol can also be employed for compound screening with other rodent models that have spatial learning and memory impairments, such as transgenic mouse models of Alzheimer's disease.

Chronic temporal lobe epilepsy is associated with enhanced Alzheimer-like neuropathology in 3×Tg-AD mice.

The comorbidity between epilepsy and Alzheimer's disease (AD) is a topic of growing interest. Senile plaques and tauopathy are found in epileptic human temporal lobe structures, and individuals with AD have an increased incidence of spontaneous seizures. However, why and how epilepsy is associated with enhanced AD-like pathology remains unknown. We have recently shown ß-secretase-1 (BACE1) elevation associated with aberrant limbic axonal sprouting in epileptic CD1 mice. Here we sought to explore whether BACE1 upregulation affected the development of Alzheimer-type neuropathology in mice expressing mutant human APP, presenilin and tau proteins, the triple transgenic model of AD (3×Tg-AD). 3×Tg-AD mice were treated with pilocarpine or saline (i.p.) at 6-8 months of age. Immunoreactivity (IR) for BACE1, ß-amyloid (Aß) and phosphorylated tau (p-tau) was subsequently examined at 9, 11 or 14 months of age. Recurrent convulsive seizures, as well as mossy fiber sprouting and neuronal death in the hippocampus and limbic cortex, were observed in all epileptic mice. Neuritic plaques composed of BACE1-labeled swollen/sprouting axons and extracellular AßIR were seen in the hippocampal formation, amygdala and piriform cortices of 9 month-old epileptic, but not control, 3×Tg-AD mice. Densities of plaque-associated BACE1 and AßIR were elevated in epileptic versus control mice at 11 and 14 months of age. p-Tau IR was increased in dentate granule cells and mossy fibers in epileptic mice relative to controls at all time points examined. Thus, pilocarpine-induced chronic epilepsy was associated with accelerated and enhanced neuritic plaque formation and altered intraneuronal p-tau expression in temporal lobe structures in 3×Tg-AD mice, with these pathologies occurring in regions showing neuronal death and axonal dystrophy.

Chronic haloperidol-induced spatial memory deficits accompany the upregulation of D(1) and D(2) receptors in the caudate putamen of C57BL/6 mouse.

AIMS: Haloperidol (HAL) is an antipsychotic drug that has high affinities to the dopamine D(2), but low affinities to D(1) receptors in the brain. Of brain regions, caudate putamen (CP) has the highest levels of the D(1) and D(2) receptors. In this study we evaluated the spatial memory of C57BL/6 mice following chronic administration of HAL and measured levels of D(1) and D(2) receptors in specific brain regions, with the hypothesis that the D(1) and D(2) receptors in CP are important players in spatial memory function of the brain. MAIN METHODS: C57BL/6 mice received daily intraperitoneal injections of saline or HAL at 1.0 or 2.0mg/kg/day for 3 or 6 weeks. Two days after the last injection, spontaneous alternation of mice in a Y-maze was evaluated to measure their exploratory behavior and spatial working memory. The Morris water maze test was performed to measure their spatial learning and memory. D(1) and D(2) receptors in specific brain regions were measured by Western-blot analysis. KEY FINDINGS: HAL treatment for 6 weeks decreased the spontaneous alternation of mice in Y-maze, altered the acquisition process and impaired spatial memory in Morris water maze. The same treatment increased levels of D(1) and D(2) receptors in CP and up-regulated D(2) receptors in the hippocampus, but did not change the receptors in the prefrontal cortex. SIGNIFICANCE: These results suggest that the D(1) and D(2) receptors in CP are among the main targets of HAL and the receptors in CP play an important role in spatial learning and memory.

Age-related intraneuronal elevation of αII-spectrin breakdown product SBDP120 in rodent forebrain accelerates in 3×Tg-AD mice.

Spectrins line the intracellular surface of plasmalemma and play a critical role in supporting cytoskeletal stability and flexibility. Spectrins can be proteolytically degraded by calpains and caspases, yielding breakdown products (SBDPs) of various molecular sizes, with SBDP120 being largely derived from caspase-3 cleavage. SBDPs are putative biomarkers for traumatic brain injury. The levels of SBDPs also elevate in the brain during aging and perhaps in Alzheimer's disease (AD), although the cellular basis for this change is currently unclear. Here we examined age-related SBDP120 alteration in forebrain neurons in rats and in the triple transgenic model of AD (3×Tg-AD) relative to non-transgenic controls. SBDP120 immunoreactivity (IR) was found in cortical neuronal somata in aged rats, and was prominent in the proximal dendrites of the olfactory bulb mitral cells. Western blot and densitometric analyses in wild-type mice revealed an age-related elevation of intraneuronal SBDP120 in the forebrain which was more robust in their 3×Tg-AD counterparts. The intraneuronal SBDP120 occurrence was not spatiotemporally correlated with transgenic amyloid precursor protein (APP) expression, ß-amyloid plaque development, or phosphorylated tau expression over various forebrain regions or lamina. No microscopically detectable in situ activated caspase-3 was found in the nuclei of SBDP120-containing neurons. The present study demonstrates the age-dependent intraneuronal presence of an αII-spectrin cleavage fragment in mammalian forebrain which is exacerbated in a transgenic model of AD. This novel neuronal alteration indicates that impairments in membrane protein metabolism, possibly due to neuronal calcium mishandling and/or enhancement of calcium sensitive proteolysis, occur during aging and in transgenic AD mice.

BACE1 elevation is associated with aberrant limbic axonal sprouting in epileptic CD1 mice.

The brain is capable of remarkable synaptic reorganization following stress and injury, often using the same molecular machinery that governs neurodevelopment. This form of plasticity is crucial for restoring and maintaining network function. However, neurodegeneration and subsequent reorganization can also play a role in disease pathogenesis, as is seen in temporal lobe epilepsy and Alzheimer's disease. ß-Secretase-1 (BACE1) is a protease known for cleaving ß-amyloid precursor protein into ß-amyloid (Aß), a major constituent in amyloid plaques. Emerging evidence suggests that BACE1 is also involved with synaptic plasticity and nerve regeneration. Here we examined whether BACE1 immunoreactivity (IR) was altered in pilocarpine-induced epileptic CD1 mice in a manner consistent with the synaptic reorganization seen during epileptogenesis. BACE1-IR increased in the CA3 mossy fiber field and dentate inner molecular layer in pilocarpine-induced epileptic mice, relative to controls (saline-treated mice and mice 24-48 h after pilocarpine-status), and paralleled aberrant expression of neuropeptide Y. Regionally increased BACE1-IR also occurred in neuropil in hippocampal area CA1 and in subregions of the amygdala and temporal cortex in epileptic mice, colocalizing with increased IR for growth associated protein 43 (GAP43) and polysialylated-neural cell adhesion molecule (PSA-NCAM), but reduced IR for microtubule-associated protein 2 (MAP2). These findings suggest that BACE1 is involved in aberrant limbic axonal sprouting in a model of temporal lobe epilepsy, warranting further investigation into the role of BACE1 in physiological vs. pathological neuronal plasticity.

BACE1 elevation is involved in amyloid plaque development in the triple transgenic model of Alzheimer's disease: differential Aß antibody labeling of early-onset axon terminal pathology.

ß-amyloid precursor protein (APP) and presenilins mutations cause early-onset familial Alzheimer's disease (FAD). Some FAD-based mouse models produce amyloid plaques, others do not. ß-Amyloid (Aß) deposition can manifest as compact and diffuse plaques; it is unclear why the same Aß molecules aggregate in different patterns. Is there a basic cellular process governing Aß plaque pathogenesis? We showed in some FAD mouse models that compact plaque formation is associated with a progressive axonal pathology inherent with increased expression of ß-secretase (BACE1), the enzyme initiating the amyloidogenic processing of APP. A monoclonal Aß antibody, 3D6, visualized distinct axon terminal labeling before plaque onset. The present study was set to understand BACE1 and axonal changes relative to diffuse plaque development and to further characterize the novel axonal Aß antibody immunoreactivity (IR), using triple transgenic AD (3xTg-AD) mice as experimental model. Diffuse-like plaques existed in the forebrain in aged transgenics and were regionally associated with increased BACE1 labeled swollen/sprouting axon terminals. Increased BACE1/3D6 IR at axon terminals occurred in young animals before plaque onset. These axonal elements were also co-labeled by other antibodies targeting the N-terminal and mid-region of Aß domain and the C-terminal of APP, but not co-labeled by antibodies against the Aß C-terminal and APP N-terminal. The results suggest that amyloidogenic axonal pathology precedes diffuse plaque formation in the 3xTg-AD mice, and that the early-onset axonal Aß antibody IR in transgenic models of AD might relate to a cross-reactivity of putative APP ß-carboxyl terminal fragments.