Spatial memory deficits in a mouse model of late-onset Alzheimer's disease are caused by zinc supplementation and correlate with amyloid-beta levels.

Much of the research in Alzheimer's disease (AD) that uses mouse models focuses on the early-onset form of the disease, which accounts for less than 5% of cases. In contrast, this study used a late-onset AD model to examine the interaction between increased dietary zinc (Zn) and the apolipoprotein E (ApoE) gene. ApoE ε4 is overrepresented in late-onset AD and enhances Zn binding to amyloid-ß (Aß). This study sought to determine if elevated dietary Zn would impair spatial memory in CRND8 mice (CRND8), as well as mice who carry both the mutated human amyloid precursor protein (APP) and ApoE ε4 genes (CRND8/E4). Mice were provided with either lab tap water or water enhanced with 10 ppm Zn (ZnCO3) for 4 months. At 6 months of age, spatial memory was measured by the Barnes maze. CRND8 mice exhibited significant memory deficits compared to WT mice, as shown by an increased latency to reach the escape box. For the CRND8/E4, but not the CRND8 mice, those given Zn water made significantly more errors than those on lab water. During the probe trial for the WT group, those on Zn water spent significantly less time in the target quadrant than those on lab water. These data suggest that increased dietary Zn can significantly impair spatial memory in CRND8/E4. WT mice given Zn water were also impaired on the 24-h probe trial when compared to lab water WTs. Within the CRND8/E4 group only, levels of soluble Aß were significantly correlated with average primary latencies. Within the Zn-treated CRND8/E4 group, there was a significant correlation between insoluble Aß and average primary errors. Levels of the zinc transporter 3, ZnT3, were negatively correlated with soluble Aß (p < 0.01). These findings are particularly relevant because increased intake of dietary supplements, such as Zn, are common in the elderly-a population already at risk for AD. Given the effects observed in the CRND8/E4 mice, ApoE status should be taken into consideration when evaluating the efficacy of therapies targeting metals.

The effect of metals on spatial memory in a transgenic mouse model of Alzheimer's disease.

The amyloid-ß protein (Aß) is a metalloprotein with affinity for the metal ions zinc (Zn), copper (Cu), and iron (Fe), which are found in high concentrations in the plaques of Alzheimer's disease (AD). Increasing attention is focused on the role of these metals in AD, and much of the evidence suggests a dyshomeostasis between these metal ions may significantly affect Aß aggregation and deposition in the brain. While the effect of these metals on Aß has been shown in vitro, there is less behavioral data supporting a direct role in cognitive impairment. In order to investigate the cognitive consequences of metal dyshomeostasis, we sought to directly increase metal levels in the brain by dietary means in a transgenic mouse model (Tg2576). We have now examined the effect of increased Zn (10 ppm) and Fe (10 ppm) levels in the drinking water in the Tg2576 mouse. Since increased dietary Zn can lead to Cu deficiency, a Zn group supplemented with copper was also examined (Zn (10 ppm)+Cu (0.025 ppm)). Significant increases in latency and fewer platform crossings on probe trials, which are considered measures of spatial memory impairment, were seen in both Fe and Zn supplemented transgenic mice, compared to those raised on lab water. No significant differences were seen between the Zn + Cu group and in transgenic mice raised on lab water. These data suggest that the negative consequences of Zn may be due to a reduction in copper levels and, therefore, an imbalance between these metal ions rather than a direct effect of increased Zn.

Alterations in fear response and spatial memory in pre- and post-natal zinc supplemented rats: remediation by copper.

The role of zinc in the nervous system is receiving increased attention. At a time when dietary fortification and supplementation have increased the amount of zinc being consumed, little work has been done on the effects of enhanced zinc on behavior. Both zinc and copper are essential trace minerals that are acquired from the diet; under normal conditions the body protects against zinc overload, but at excessive dosages, copper deficiency has been seen. In order to examine the effect of enhanced metal administration on learning and memory, Sprague Dawley rats were given water supplemented with 10ppm Zn, 10ppm Zn+0.25ppm Cu, or normal lab water, during pre- and post-natal development. Fear conditioning tests at 4months showed significantly higher freezing rates during contextual retention and extinction and cued extinction for rats drinking water supplemented with zinc, suggesting increased anxiety compared to controls raised on lab water. During the MWM task at 9months, zinc-enhanced rats had significantly longer latencies to reach the platform compared to controls. The addition of copper to the zinc supplemented water brought freezing and latency levels closer to that of controls. These data demonstrate the importance of maintaining appropriate intake of both metals simultaneously, and show that long-term supplementation with zinc may cause alterations in memory.