Gary W. Arendash

A|[beta]| peptide vaccination prevents memory loss in an animal model of Alzheimer's disease

Vaccinations with amyloid-β peptide (AB) can dramatically reduce amyloid deposition in a transgenic mouse model of Alzheimers disease. To determine if the vaccinations had deleterious or beneficial functional consequences, we tested eight months of Aβ vaccination in a different transgenic model for Alzheimers disease in which mice develop learning deficits as amyloid accumulates . Here we show that vaccination with Aβ protects transgenic mice from the learning and age-related memory deficits that normally occur in this mouse model for Alzheimers disease. During testing for potential deleterious effects of the vaccine, all mice performed superbly on the radial-arm water-maze test of working memory. Later, at an age when untreated transgenic mice show memory deficits, the Aβ-vaccinated transgenic mice showed cognitive performance superior to that of the control transgenic mice and, ultimately, performed as well as nontransgenic mice. The Aβ-vaccinated mice also had a partial reduction in amyloid burden at the end of the study. This therapeutic approach may thus prevent and, possibly, treat Alzheimers dementia.

Caffeine protects Alzheimer’s mice against cognitive impairment and reduces brain β-amyloid production

A recent epidemiological study suggested that higher caffeine intake over decades reduces the risk of Alzheimers disease (AD). The present study sought to determine any long-term protective effects of dietary caffeine intake in a controlled longitudinal study involving AD transgenic mice. Caffeine (an adenosine receptor antagonist) was added to the drinking water of amyloid precursor protein, Swedish mutation (APPsw) transgenic (Tg) mice between 4 and 9 months of age, with behavioral testing done during the final 6 weeks of treatment. The average daily intake of caffeine per mouse (1.5 mg) was the human equivalent of 500 mg caffeine, the amount typically found in five cups of coffee per day. Across multiple cognitive tasks of spatial learning/reference memory, working memory, and recognition/identification, Tg mice given caffeine performed significantly better than Tg control mice and similar to non-transgenic controls. In both behaviorally-tested and aged Tg mice, long-term caffeine administration resulted in lower hippocampal beta-amyloid (Abeta) levels. Expression of both Presenilin 1 (PS1) and beta-secretase (BACE) was reduced in caffeine-treated Tg mice, indicating decreased Abeta production as a likely mechanism of caffeines cognitive protection. The ability of caffeine to reduce Abeta production was confirmed in SweAPP N2a neuronal cultures, wherein concentration-dependent decreases in both Abeta1-40 and Abeta1-42 were observed. Although adenosine A(1) or A(2A) receptor densities in cortex or hippocampus were not affected by caffeine treatment, brain adenosine levels in Tg mice were restored back to normal by dietary caffeine and could be involved in the cognitive protection provided by caffeine. Our data demonstrate that moderate daily intake of caffeine may delay or reduce the risk of AD.

Blueberry Supplementation Enhances Signaling and Prevents Behavioral Deficits in an Alzheimer Disease Model

Abstract Previously, we showed that blueberry (BB) supplementation reversed the deleterious effects of aging on motor behavior and neuronal signaling in senescent rodents. We now report that BB-fed (from 4 months of age) APP+PS1 transgenic mice showed no deficits in Y-maze performance (at 12 months of age) with no alterations in amyloid beta burden. It appeared that the protective mechanisms are derived from BB-induced enhancement of memory-associated neuronal signaling (e.g. extracellular signal-regulated kinase) and alterations in neutral sphingomyelin-specific phospholipase C activity. Thus, our data indicate for the first time that it may be possible to overcome genetic predispositions to Alzheimer disease through diet.

Progressive, age-related behavioral impairments in transgenic mice carrying both mutant amyloid precursor protein and presenilin-1 transgenes.

This study provides a comprehensive behavioral characterization during aging of transgenic mice bearing both presenilin-1 (PS1) and amyloid precursor protein (APP(670,671)) mutations. Doubly transgenic mice and non-transgenic controls were evaluated at ages wherein beta-amyloid (Abeta) neuropathology in APP+PS1 mice is low (5-7 months) or very extensive (15-17 months). Progressive cognitive impairment was observed in transgenic mice for both water maze acquisition and radial arm water maze working memory. However, transgenicity did not affect Y-maze alternations, circular platform performance, standard water maze retention, or visible platform recognition at either age, nor did transgenicity affect anxiety levels in elevated plus-maze testing. In sensorimotor tasks, transgenic mice showed a progressive increase in open field activity, a progressive impairment in string agility, and an early-onset impairment in balance beam. None of these sensorimotor changes appeared to be contributory to any cognitive impairments observed, however. Non-transgenic mice showed no progressive behavioral change in any measure evaluated. Given the age-related cognitive impairments presently observed in APP+PS1 transgenic mice and their progressive Abeta deposition/neuroinflammation, Abeta neuropathology could be involved in these progressive cognitive impairments. As such, the APP+PS1 transgenic mouse offers unique opportunities to develop therapeutics to treat or prevent Alzheimers Disease through modulation of Abeta deposition/neuroinflammation.

Effects of discrete lesions of the sexually dimorphic nucleus of the preoptic area or other medial preoptic regions on the sexual behavior of male rats

The sexually dimorphic nucleus of the rat medial preoptic area (SDN-POA) has a volume five times larger in the adult male compared with that of the adult female. In the present study, the effects of discrete electrolytic destruction of the SDN-POA or other specific medial preoptic (MPOA) regions on masculine sexual behavior were determined in adult, sexually experienced male rats. Small lesions encompassing the SDN-POA had no effect on the maintenance of copulatory behavior. Lesions of similar size placed within the ventral or anterio-dorsal MPOA also did not consistently affect the display of masculine sexual behavior. However, animals that received small lesions within their dorsal MPOA showed a substantial, long-term decrease in number of mounts, intromissions, and ejaculations compared to these parameters in sham-lesioned control rats, thus indicating a lesion-induced disruption of those neural mechanisms mediating these behaviors. Collectively these data suggest that the SDN-POA is not critical for a full expression of male sexual behavior and that the dorsal MPOA may be more important than other MPOA regions for copulatory behavior.

Correlation between cognitive deficits and Aβ deposits in transgenic APP+PS1 mice

Doubly transgenic mAPP+mPS1 mice (15-16 months) had impaired cognitive function in a spatial learning and memory task that combined features of a water maze and a radial arm maze. Nontransgenic mice learned a new platform location each day during 4 consecutive acquisition trials, and exhibited memory for this location in a retention trial administered 30 min later. In contrast, transgenic mice were, on average, unable to improve their performance in finding the hidden platform over trials. The cognitive performance of individual mice within the transgenic group were inversely related to the amount of Abeta deposited in the frontal cortex and hippocampus. These findings imply that mAPP+mPS1 transgenic mice develop deficits in cognitive ability as Abeta deposits increase. These data argue that radial arm water maze testing of doubly transgenic mice may be a useful behavioral endpoint in evaluating the functional consequences of potential AD therapies, especially those designed to reduce Abeta load.

Behavioral characterization of the Tg2576 transgenic model of Alzheimer's disease through 19 months

Behavioral characterization of Alzheimers disease (AD) transgenic models over multiple time points during aging has been largely inadequate, usually being limited to one or two cognitive-based tasks. In this context, the present study utilized a comprehensive 6-week behavioral battery to characterize sensorimotor and cognitive performance of Tg2576 AD transgenic (Tg+) mice and nontransgenic (Tg-) controls aged 3, 9, 14, and 19 months. Compared collectively to Tg- mice over all four time points, Tg+ mice were impaired in Y-maze spontaneous alternation, visible platform recognition, and several sensorimotor tasks; Tg+ mice also showed an overall increase in activity measures. The deficits in visible platform became evident by 9 months of age, while those in sensorimotor tasks became clearly manifest by 14 months. Although the behavioral impairments exhibited by Tg+ mice were usually progressive through 19 months, Tg- animals also showed similar progressive decline in the same behavioral measures; thus, no task revealed a progressive behavioral decline exclusive to Tg+ mice. Moreover, although the 6-week behavioral battery included six cognitively based tasks (i.e., Y-maze, visible platform, Morris water maze, circular platform, passive avoidance, and active avoidance), behavioral analysis through 19 months revealed Tg+ mice to be impaired in only the Y-maze and visible platform tasks. Consequently, Tg2576 mice do not exhibit widespread, profound cognitive impairment, even into old age. This may reflect their predominant C57BL/6 background and an apparent inability of the mutant transgene to profoundly alter performance therein.

Improved learning and memory in aged rats with chronic administration of the nicotinic receptor agonist GTS-21

The ability of two synthetic nicotine receptor ligands, TGS-21 and DMAB, to chronically enhance the cognitive function of aged rats was evaluated in three diverse tasks and compared to the cognition-enhancing effects of nicotine administration. 15 min prior to daily behavioral testing, aged 22-24 month old rats received an i.p. injection of nicotine (.02 mg/kg), GTS-21 (1 mg/kg), DMAB (2mg/kg), or saline vehicle and were tested in either one-way active avoidance pole jumping, Lashley III maze, or a 17-arm radial maze. GTS-21 pretreatment was as effective as nicotine for enhancing the acquisition of aged rats in both one-way active avoidance and Lashley III maze training. In 17-arm radial maze testing, GTS-21 improved both general learning and reference (long-term) memory to the same extent as nicotine. Although DMAB pretreatment enhanced reference memory in 17-arm radial maze testing to the same as nicotine, it did not affect general learning in this complex task and did not exert any cognition-enhancing effects in Lashley III maze training. These results indicate that GTS-21 has cognition-enhancing abilities in aged rats that are comparable to those of nicotine in a variety of behavioral tasks. Since GTS-21 acts preferentially on brain nicotinic receptors and is less toxic than nicotine, thses results further indicate that GTS-21 may have substantive therapeutic value in the treatment of age-associated memory impairment (AAMI) and/or Alzheimers disease.

Protection against cognitive deficits and markers of neurodegeneration by long-term oral administration of melatonin in a transgenic model of Alzheimer disease.

Abstract:  The neurohormone melatonin has been reported to exert anti‐β‐amyloid aggregation, antioxidant, and anti‐inflammatory actions in various in vitro and animal models. To comprehensively determine the potential for long‐term melatonin treatment to protect Alzheimer’s transgenic mice against cognitive impairment and development of β‐amyloid (Aβ) neuropathology, we administered melatonin (100 mg/L drinking water) to APP + PS1 double transgenic (Tg) mice from 2–2.5 months of age to their killing at age 7.5 months. A comprehensive behavioral battery administered during the final 6 weeks of treatment revealed that Tg mice given melatonin were protected from cognitive impairment in a variety of tasks of working memory, spatial reference learning/memory, and basic mnemonic function; Tg control mice remained impaired in all of these cognitive tasks/domains. Immunoreactive Aβ deposition was significantly reduced in hippocampus (43%) and entorhinal cortex (37%) of melatonin‐treated Tg mice. Although soluble and oligomeric forms of Aβ1‐40 and 1‐42 were unchanged in the hippocampus and cortex of the same melatonin‐treated Tg mice, their plasma Aβ levels were elevated. These Aβ results, together with our concurrent demonstration that melatonin suppresses Aβ aggregation in brain homogenates, are consistent with a melatonin‐facilitated removal of Aβ from the brain. Inflammatory cytokines such as tumor necrosis factor (TNF)‐α were decreased in hippocampus (but not plasma) of Tg+ melatonin mice. Finally, the cortical mRNA expression of three antioxidant enzymes (SOD‐1, glutathione peroxidase, and catalase) was significantly reduced to non‐Tg levels by long‐term melatonin treatment in Tg mice. Thus, melatonin’s cognitive benefits could involve its anti‐Aβ aggregation, anti‐inflammatory, and/or antioxidant properties. Our findings provide support for long‐term melatonin therapy as a primary or complementary strategy for abating the progression of Alzheimer disease.

Metals and free radicals in neurodegeneration.

Substantial evidence has accumulated implicating metals and free radicals in the pathogenesis of the major neurodegenerative disorders (Parkinsons disease, Alzheimers disease, and amyotrophic lateral sclerosis). Metal-induced oxidant stress can damage critical biological molecules and initiate a cascade of events including mitochondrial dysfunction, excitotoxicity, and a rise in cytosolic free calcium, leading to cell death. In Parkinsons disease and Alzheimers disease there is evidence of oxidative stress in affected brain regions, as indicated by increased metal accumulation (which promotes free radical formation), decreased antioxidant levels (which protect against free radical formation), and oxidative damage. Recently, studies of the familial form of amyotrophic lateral sclerosis have detected mutations in the gene that encodes superoxide dismutase, which is one of the bodys primary oxidant defense mechanisms. Mice that are transfected with the human mutant superoxide dismutase gene develop an amyotrophic lateral sclerosis syndrome. These studies demonstrate that oxidant stress can initiate the development of a chronic progressive neurodegenerative disorder.Substantial evidence has accumulated implicating metals and free radicals in the pathogenesis of the major neurodegenerative disorders (Parkinsons disease, Alzheimers disease, and amyotrophic lateral sclerosis). Metal-induced oxidant stress can damage critical biological molecules and initiate a cascade of events including mitochondrial dysfunction, excitotoxicity, and a rise in cytosolic free calcium, leading to cell death. In Parkinsons disease and Alzheimers disease there is evidence of oxidative stress in affected brain regions, as indicated by increased metal accumulation (which promotes free radical formation), decreased antioxidant levels (which protect against free radical formation), and oxidative damage. Recently, studies of the familial form of amyotrophic lateral sclerosis have detected mutations in the gene that encodes superoxide dismutase, which is one of the bodys primary oxidant defense mechanisms. Mice that are transfected with the human mutant superoxide dismutase gene develop an amyotrophic lateral sclerosis syndrome. These studies demonstrate that oxidant stress can initiate the development of a chronic progressive neurodegenerative disorder.