About the Authors:
Paul A. Adlard
* E-mail: [email protected]
Affiliations Oxidation Biology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia, Synaptic Neurobiology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia, Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia
Laura Bica
Affiliations Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia, Centre for Neuroscience, The University of Melbourne, Parkville, Victoria, Australia
Anthony R. White
Affiliations Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia, Centre for Neuroscience, The University of Melbourne, Parkville, Victoria, Australia
Milawaty Nurjono
Affiliation: Oxidation Biology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia
Gulay Filiz
Affiliation: Oxidation Biology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia
Peter J. Crouch
Affiliations Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia, Centre for Neuroscience, The University of Melbourne, Parkville, Victoria, Australia
Paul S. Donnelly
Affiliations Bio21 Molecular Science and Biotechnology Institute, The University of Melbourne, Parkville, Victoria, Australia, School of Chemistry, The University of Melbourne, Parkville, Victoria, Australia
Roberto Cappai
Affiliations Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia, Bio21 Molecular Science and Biotechnology Institute, The University of Melbourne, Parkville, Victoria, Australia
David I. Finkelstein
Contributed equally to this work with: David I. Finkelstein, Ashley I. Bush
Affiliations Oxidation Biology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia, Synaptic Neurobiology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia, Centre for Neuroscience, The University of Melbourne, Parkville, Victoria, Australia
Ashley I. Bush
Contributed equally to this work with: David I. Finkelstein, Ashley I. Bush
Affiliations Oxidation Biology Laboratory, The Mental Health Research Institute, Parkville, Victoria, Australia, Department of Pathology, The University of Melbourne, Parkville, Victoria, Australia
Introduction
Alzheimer's disease (AD) is characterized by deficits in higher order cognitive processes. One of the principal substrates for this dysfunction is spine/synaptic loss, which studies in AD animal models have demonstrated is most pronounced in the immediate vicinity of Aβ plaques [1], [2], [3]. Furthermore, Aβ oligomers impair NMDAR-dependent signalling cascades, ultimately resulting in the progressive loss of dendritic spines and glutamatergic synapses [4], [5], [6].
One of the mechanisms likely to mediate such deleterious effects is perturbed trafficking of essential synaptic metal ions, such as zinc. Synaptic Zn2+ functions as a neuronal messenger and a modulator of synaptic transmission and plasticity through targeted interactions with proteins such as TrkB and NMDAR2b [7], [8]. The attraction of Aβ oligomers to Zn2+ emanating from the glutamatergic synapse selectively occludes the NMDAR2b subunit [9]. Thus, the sequestration of Zn2+ in oligomeric Aβ-Zn complexes may lead to a reduction in zinc turnover at the synapse, limiting the trans-synaptic movement of zinc to modulate post-synaptic targets, and resulting in impaired cognition.
Drug candidates clioquinol (CQ) and PBT2 (Prana Biotechnology Ltd) have a moderate affinity for metal ions, and rather than deplete biological metals in cell culture, promote the uptake of Cu and Zn [10]. We have previously demonstrated [10] that brief administration of CQ and PBT2 (11 days, 30 mg/kg) to both Tg2576 and APP/PS1 transgenic mice resulted in decreased brain Aβ burden with rapid (within 5 days) and marked improvements in learning and memory performance on the Morris water maze. PBT2 also induced cognitive benefits in a phase IIa clinical trial [11], [12]. To understand the mechanisms that underlie this restoration of cognition, we studied the effect of PBT2 on synaptic plasticity-related endpoints in both cell culture and Tg2576 mice.
Materials and Methods
All animal procedures were approved by the Howard Florey Institute animal ethics committee (Melbourne, Australia), and were carried out in accordance with the Australian code of practice for the care and use of animals for scientific purposes as described by the National Health and Medcial Research Council of Australia. Female Tg2576 animals were group-housed and aged to 4 or 14 months. For 11 days prior to culling, animals were given a daily oral gavage of sham (standard suspension vehicle [10]) or PBT2 (30 mg/kg, provided by Prana Biotechnology Ltd, Melbourne, Australia) in the same vehicle (n = 8–12 mice/group total; split between golgi and biochemical analyses). One hour following the last drug dose, animals were culled and the brain either immediately processed for Golgi analysis, or frozen at −80°C for subsequent biochemical analyses. The dose of PBT2 was chosen based upon our own historical data, where we have shown that this level of exposure to the compound effectively modulates a number of biochemical and behavioural parameters in various transgenic mouse models of AD, but does not alter bulk brain metal levels [10]. With regards to how this relates to a human dose, based upon FDA guidelines a dose of 30 mg/kg in a mouse equates to a dose of 183 mg/day in a 75 kg man. Our published human clinical trial data demonstrated that PBT2 was found to be therapeutic at 250 mg/day [11], [12].
Golgi staining
A subset of animals (n = 3–5 mice/group) were deeply anaesthetized with sodium pentobarbitone (100 mg/kg) and then transcardially perfused with 0.01 M cold PBS. Brains were then rapidly removed and cut into 4 mm blocks. The blocks containing the hippocampus were incubated in rapid golgi solutions (Rapid Golgi Stain Kit, MTR scientific), based on the methods of Glasser and Van der Loos [13]. The blocks were infused with a solution containing potassium dichromate, potassium chromate and mercuric chloride for two weeks. The blocks were then snap frozen and cut at 90 µm using a microtome (Cryostat, Leica CM18-50, Leica Microsystems, Nussloch GmbH, Germany). Sections were collected at the level of the hippocampus (bregma −1.40 to −2.70) and thaw-mounted onto gelatinized microscope slides. The slides were dried, dehydrated, cleared with xylene and mounted with distyrene plasticized xylene (DPX). Golgi-treated brain tissue was analysed with a light microscope with an oil immersion lens (63x, NA 1.3; Leica DM4000B, Leica Microsystems; with a further magnification from the projection lens to the camera (10x) used for all measurements, providing a total magnification of 630 times). The whole neuron was traced manually.
Five neurons from each animal (n = 3–5 animals/group) were randomly selected for hippocampal spine analysis. Neurons were selected only if; they were clearly identified as being from the CA1 subfield, the neurons appeared completely filled and they were far enough from the neighbouring Golgi stained cells to be individually identified. Tertiary or greater order apical and basal dendrites (n = 5 apical and n = 5 basal) were selected and analysed to determine spine density, dendritic length and dendritic number (a cartoon outlining this method is shown in Figure S1). Thus, 50 dendrites were sampled from each animal. The standard deviations indicate the uniformity of the analyses and demonstrate that this is a representative sampling.
Biochemical analyses
Western blot, as previously described [14], was used for the quantitation of protein levels in individual hippocampi taken from a subset of animals (n = 5–7 mice/group). The antibodies utilized are outlined in Table S1.
Cell culture
Diaminosarcophagine (1,8-diamino-3,6,10,13,16,19 hexaazabicyclo[6.6.6]icosane), abbreviated to (NH2)2sar and given the trivial name “diamsar”, was synthesised as previously reported [15].
For biochemical studies, SH-SY5Y cells were utilised (in DMEM+10% serum), cells harvested after one hour exposure to the various treatments and then western blots performed (n = 6 replicates for each treatment).
Neurite outgrowth studies, which were conducted separately from the biochemical studies, utilised PC12 cells (grown in DMEM+10% fetal bovine serum) treated with NGF at 50 ng/ml in serum-free DMEM for 48 h. DMSO vehicle, 150 nM PBT2, 150 nM CuCl2, 150 nM ZnCl2, 150 nM PBT2-Zn (equimolar PBT2 and ZnCl2), 5 µM diamsar, 150 nM PBT2 plus 5 µM diamsar or 150 nM PBT2-Zn plus 5 µM diamsar were then added for 24 h. Treated cells were photographed and Image J software (NIH) used to determine the proportion of cells that had neurites 2x or longer than the width of the cell body, and to obtain a mean neurite length (n≥6 images from 3 cultures for each treatment).
Statistics
All analyses were performed by an operator that was blinded to the experimental conditions. An ANOVA followed by a post-hoc Tukey's multiple comparison test was performed for all comparisons (GraphPad Prism Version 5.0b).
Results
Initial assessment of 4 month old wildtype animals did not reveal any significant effect of PBT2 on dendritic spine density (apical = −7.5% and basal = −1.8%; both compared to sham-treated wildtypes), suggesting that there was no generic effect of PBT2 on this endpoint. This is consistent with our previous report, where there was no effect of PBT2 on the performance of wildtype animals in the Morris water maze [10].
PBT2 increases hippocampal apical spine density in Tg2576 mice
Consistent with previous reports [16], [17], we demonstrated that Tg2576 mice have decreased apical spine density compared to age-matched WTs (sample image in Figure S2). These deficits occurred as early as 4 months of age (−13%, p<0.01) and were more severe at 14 months of age (−31%, p<0.001) (Figure 1A).
[Figure omitted. See PDF.]
Figure 1. Dendritic spine analysis in Tg2576 mice and wildtype littermates.
(A) Tg2576 animals have deficits in apical dendritic spine density at both four (n = 4) and fourteen (n = 5) months of age, as compared to WT mice (n = 4 at four months; n = 5 at fourteen months), that are reversed by short-term (11 days) PBT2-treatment (n = 3 at both age points). There are also age-related decreases in apical spine density in both the Tg groups. (B) There is a significant increase in basal spine density in fourteen month old Tg animals treated with PBT2. There is also an age-related decrease in basal spine density in WT animals. (C) There were no significant differences in apical or basal dendrite number across the experiment. (D) There were no significant differences in apical or basal dendrite length across the experiment. Values are mean ± SEM. **p<0.01, ***p<0.001.
https://doi.org/10.1371/journal.pone.0017669.g001
Treatment of young Tg2576 mice with PBT2 for 11 days resulted in an increase in apical spine density (+17%, p<0.001) that abolished the deficits seen in younger sham-treated Tg animals (Figure 1A). In older animals, PBT2-treatment also resulted in an increase in apical spine density (+32%, p<0.001), which approached WT levels (Figure 1A).
There was also an age-related decrease in apical spine density evident only in both Tg groups (sham-treated, −24%, p = 0.001; PBT2-treated, −15%, p<0.0001) (Figure 1A).
PBT2 increases basal spine density in Tg2576 mice
There were no genotype-specific changes in basal spine density at either age (Figure 1B). There was, however, an age-related deficit in basal spine density observed in WT (−15%, p = 0.0017) and a similar trend in the sham-treated Tg mice. In contrast, 14 month old Tg2576 mice treated with PBT2 had greater basal spine density (+26%, p<0.001) than sham-treated controls, with basal spine density reaching similar levels to the 4 month old mice (Figure 1B).
There were no significant changes in dendritic number or length observed in 14 month old animals treated with PBT2 (Figure 1C and 1D).
PBT2 restores biochemical substrates of learning/memory in Tg2576 mice
To explore biochemical mechanisms underlying these effects, we assessed the levels of various proteins involved in plasticity (Figure 2A; sample blots shown in Figure S3). Both BDNF and its precursor, pro-BDNF, were increased (+19%, p = 0.04; +19%, p = 0.02, respectively) in PBT2-treated compared to sham-treated Tg2576 mice. The high-affinity receptor for BDNF, TrkB, showed a trend to elevation in PBT2-treated Tg2576 mice (+91%, p = 0.06). In addition, CamKII was elevated (+57%, p = 0.005) following PBT2 treatment.
[Figure omitted. See PDF.]
Figure 2. Biochemical profiles in Tg2576 and wildtype littermate mice and in cell culture.
(A) Tg2576 mice have significant deficits in a number of proteins, as compared to age-matched wildtype controls, and PBT2-treatment significantly increases the expression of a number of these proteins to the levels seen in the control mice. Values have been normalized to the mean of Tg Sham group = 100. (B) The effect of PBT2 on NMDAR1 protein levels in SH-SY5Y cells is abolished in the presence of the high affinity chelator, diamsar (n = 6/treatment). *p<0.05, **p<0.01, #p = 0.06.
https://doi.org/10.1371/journal.pone.0017669.g002
PBT2 treatment of Tg2576 mice also increased levels of NMDAR1A and NMDAR2A (+126%, p = 0.02; +70%, p = 0.05 respectively), with a trend to an elevation in NMDAR2B (+105%, p = 0.06). As one of the most significantly upregulated proteins we also sought to test the metal-dependence of this effect in vitro. PBT2 treatment resulted in an increase in NMDAR1A protein levels (+29%, p = 0.02) that was abolished by diamsar (−49%, p<0.0001). Diamsar also reduced NMDAR1A protein levels below that found in controls (−34%, p = 0.002) (Figure 2B).
Other proteins examined in the in vivo tissues, including AMPAr, SNAP25, synaptotagmin and PSD95 were not significantly altered, although Creb trended towards an increase following PBT2-treatment (Figure S4).
PBT2 increases neuritogenesis in a metal-dependent manner in vitro
Although there was no significant effect of PBT2 on dendritic length in vivo, our own qualitative in vitro observations (data not shown) suggested that PBT2 was altering the appearance of cells grown in culture. As it is possible that the treatment period used in our in vivo studies was not sufficient to evince this morphological change, or that there was not sufficiently high local concentrations of drug to see an effect, we sought to examine the trophic effects of PBT2 in vitro and to assess the reliance of any effects on the entry of metals into cells.
PBT2 treatment resulted in a robust increase in neurite outgrowth (+200%, p = 0.006) (Figure 3A), which we hypothesized was due to complexing with Zn or Cu in the buffer and then increasing cellular metal content via its ionophore activity. Indeed, neurite outgrowth was enhanced when PBT2 was complexed with either Cu or Zn (+300%, p<0.0003) (Figure 3A). Cu and Zn alone, however, did not significantly increase neurite outgrowth (Figure 3A).
[Figure omitted. See PDF.]
Figure 3. The metal-dependent effect of PBT2 on neurite outgrowth.
The effects of copper and zinc alone (0.15 µM) or complexed to PBT2 (0.15 µM) were assessed. (A) PBT2 induces an increase in neurite outgrowth in PC12 cells that is exaggerated when PBT2 is complexed to either copper or zinc (n = 6/treatment). (B) The neuritogenic effect of PBT2 is abolished in the presence of the high affinity chelator, diamsar (n = 9/treatment). Neurite outgrowth in PC12 cells, under control (C), PBT2 (D) and PBT + diamsar (E) conditions is shown in the bottom micrographs (scale bar = 200 µm). Values are mean ± SEM. **p<0.01, ***p<0.001.
https://doi.org/10.1371/journal.pone.0017669.g003
Furthermore, PBT2-induced neuritogenesis required cellular metal influx, since it was abolished by co-administration of the high affinity metal chelator, diamsar (Figure 3B–3E). MTT assay demonstrated that none of the treatments impaired viability (+55%, p = 0.04) (Figure S5).
Discussion
We have demonstrated that brief administration of PBT2 in a transgenic mouse model of AD rectifies deficits in key biochemical memory substrates, which may explain the rapid improvement in cognition seen in these animals during treatment. We also demonstrated that these effects could be mediated by metal ion uptake, consistent with the hypothesized mechanism of action for this class of compound [10].
We have recently demonstrated that the short-term administration of the ionophores CQ and PBT2 to both APP/PS1 and Tg2576 mice significantly reduced Aβ burden and the hyper-phosphorylation of tau [10]. These changes in classical AD biomarkers were accompanied by a concomitant increase in synaptophysin, a surrogate marker for synapses, and a striking restoration of performance on the Morris water maze. The behavioural effects were evident after less than a week of treatment, and over the course of the study the ionophore-treated Tg animals performed as well as or better than wildtype control mice. These benefits were likely to be mediated by biochemical and synaptic benefits that may result from both a reduction in Aβ burden and the mobilization of Zn and Cu trapped in Aβ aggregates.
Consistent with previous reports [16], [17], and actual AD [18], [19], [20], we found that Tg2576 mice have deficits in dendritic spine density (Figure 1). This was observed at 4 months of age and was more pronounced by 14 months of age. PBT2 treatment resulted in a near-complete restoration of apical spine density in both young and old Tg animals, in addition to reversing the age-related decrease in basal spine density in the Tg animals (Figure 1).
Such anatomical changes must be supported by local protein synthesis. We therefore analysed levels of key proteins involved in synaptic function to gauge the impact of PBT2 on plasticity-related events. The most prominent effects of PBT2 treatment were on NMDA receptors (NMDAR1, 2A, 2B), which were increased ∼100% above levels in sham-treated Tg mice (Figure 2). This is consistent with the increase we observed in spine density (Figure 1), which express glutamate receptors (such as NMDAr), whose activation promote spine stability [21], [22], [23]. The downstream signalling events from these glutamate receptors are mediated by a variety of proteins, including CaMKII, which similarly showed a >50% increase following PBT2 treatment (Figure 2). Signalling proteins such as CaMKII, which is upregulated within the post-synaptic density following neuronal activity, modulate glutamate receptor levels and spine morphology [24], [25], [26]. Indeed, the induction of LTP results in an enlargement and proliferation of spines in a NMDAr and CaMKII-dependent manner [27], [28], [29], [30], [31], [32]. Additionally, spine survival is promoted by elements of the BDNF pathway [33]. BDNF, pro-BDNF, and TrkB, were all elevated following PBT2 treatment (Figure 2), consistent with a neurotrophic response.
Thus, PBT2 treatment results in a significant upregulation of key proteins that is likely to result in a more active synapse, increased structural plasticity and enhanced cognitive function. In Tg2576 mice, where many of these pathways are deficient in comparison to WT mice, this may explain the ability of PBT2 to rapidly restore cognitive function.
Our observation that the effects of PBT2 are dependent upon increasing metal uptake is consistent with our recent findings that the expression of several of these proteins are dependent on synaptic zinc content [14]. Aged ZnT3 KO animals, which have a specific absence of synaptic zinc, show significant deficits in proteins such as BDNF, pro-BDNF, TrkB and NMDA receptors. In AD, extracellular amyloid traps Zn2+ and Cu2+ [34] and may deprive the synapse of these trophic metal ions. Thus, the efficacy of PBT2 in modulating synaptic plasticity, by reversing extracellular metallostasis, may serve as one of its primary mechanisms of action underlying the improved cognition that results following treatment in both mice [10] and humans [11], [12].
Supporting Information
[Figure omitted. See PDF.]
Figure S1.
Cartoon showing the quantitation of golgi data. A schematic of the hippocampus, showing the different sub-regions (CA1-3 and dentate gyrus (DG)), is shown in (A). A representative golgi-stained image is then shown in (B), with the traced neuron shown in (C). Also shown in panel (C) is the orientation of the dendrites (basal/apical), together with the cell body (CB) and the branching of the dendrites into the primary (1), secondary (2) and tertiary (3) dendrites. The blue boxes represent the tertiary dendrites from which spine counts were made. Panel (D) shows a representative dendrite with spines (arrow).
https://doi.org/10.1371/journal.pone.0017669.s001
(TIF)
Figure S2.
Examples of golgi data. The left hand panel shows both apical and basal dendrites. The three central figures show typical line-drawings for dendrites from each of the three treatments, where there is no significant change in dendrite length or density. The images on the right hand side show images used for calculating spine density. The Tg animals clearly have a decreased number of spines per neurite, as compared to WT mice, and this is normalised by PBT2 treatment.
https://doi.org/10.1371/journal.pone.0017669.s002
(TIF)
Figure S3.
Representative western blots. (A) shows the various antibodies used in Figure 2A in the main text, while (B) shows a representative blot for the data presented in Figure 2B in the main text. All blots were normalised to GAPDH as a loading control. WT = wildtype; Cont = control.
https://doi.org/10.1371/journal.pone.0017669.s003
(TIF)
Figure S4.
Biochemical profile of proteins that were not significantly altered with PBT2 treatment.
https://doi.org/10.1371/journal.pone.0017669.s004
(TIF)
Figure S5.
MTT assay on SH-SY5Y cells treated with PBT2 ± diamsar. PBT2-Zn treatment results in a significant increase in cell viability. Values are normalised to control = 100% and are means ± SEM *p<0.05.
https://doi.org/10.1371/journal.pone.0017669.s005
(TIF)
Table S1.
The various antibodies used for western blot.
https://doi.org/10.1371/journal.pone.0017669.s006
(TIF)
Acknowledgments
We thank Dr. Ann Turnley for the provision of PC12 cells and Dr. Ya-Hui Hung for the provision of SH-SY5Y cells. PBT2 was kindly provided by Prana Biotechnology Ltd (www.pranabio.com).
Author Contributions
Conceived and designed the experiments: PAA ARW RC DIF. Performed the experiments: LB MN GF. Analyzed the data: PAA LB ARW MN GF DIF. Contributed reagents/materials/analysis tools: PJC PSD. Wrote the paper: PAA AIB.
Citation: Adlard PA, Bica L, White AR, Nurjono M, Filiz G, Crouch PJ, et al. (2011) Metal Ionophore Treatment Restores Dendritic Spine Density and Synaptic Protein Levels in a Mouse Model of Alzheimer's Disease. PLoS ONE 6(3): e17669. https://doi.org/10.1371/journal.pone.0017669
1. Dong H, Martin MV, Chambers S, Csernansky JG (2006) Spatial relationship between synapse loss and β-amyloid deposition in Tg2576 mice. J Comp Neurol 500: 311–321.H. DongMV MartinS. ChambersJG Csernansky2006Spatial relationship between synapse loss and β-amyloid deposition in Tg2576 mice.J Comp Neurol500311321
2. Spires TL, Meyer-Luehmann M, Stern EA, McLean PJ, Skoch J, et al. (2005) Dendritic spine abnormalities in amyloid precursor protein transgenic mice demonstrated by gene transfer and intravital multiphoton microscopy. J Neurosci 25: 7278–7287.TL SpiresM. Meyer-LuehmannEA SternPJ McLeanJ. Skoch2005Dendritic spine abnormalities in amyloid precursor protein transgenic mice demonstrated by gene transfer and intravital multiphoton microscopy.J Neurosci2572787287
3. Tsai J, Grutzendler J, Duff K, Gan W-B (2004) Fibrillar amyloid deposition leads to local synaptic abnormalities and breakage of neuronal branches. Nat Neurosci 7: 1181–1183.J. TsaiJ. GrutzendlerK. DuffW-B Gan2004Fibrillar amyloid deposition leads to local synaptic abnormalities and breakage of neuronal branches.Nat Neurosci711811183
4. Hsieh H, Boehm J, Sato C, Iwatsubo T, Tomita T, et al. (2006) AMPAR removal underlies Abeta-induced synaptic depression and dendritic spine loss. Neuron 52: 831–843.H. HsiehJ. BoehmC. SatoT. IwatsuboT. Tomita2006AMPAR removal underlies Abeta-induced synaptic depression and dendritic spine loss.Neuron52831843
5. Lacor PN, Buniel MC, Chang L, Fernandez SJ, Gong Y, et al. (2004) Synaptic targeting by Alzheimer's-related amyloid beta oligomers. J Neurosci 24: 10191–10200.PN LacorMC BunielL. ChangSJ FernandezY. Gong2004Synaptic targeting by Alzheimer's-related amyloid beta oligomers.J Neurosci241019110200
6. Lacor PN, Buniel MC, Furlow PW, Sanz Clemente A, Velasco PT, et al. (2007) A Oligomer-Induced Aberrations in Synapse Composition, Shape, and Density Provide a Molecular Basis for Loss of Connectivity in Alzheimer's Disease. J Neurosci 27: 796–807.PN LacorMC BunielPW FurlowA. Sanz ClementePT Velasco2007A Oligomer-Induced Aberrations in Synapse Composition, Shape, and Density Provide a Molecular Basis for Loss of Connectivity in Alzheimer's Disease.J Neurosci27796807
7. Nakashima AS, Dyck RH (2009) Zinc and cortical plasticity. Brain Res Rev 59: 347–373.AS NakashimaRH Dyck2009Zinc and cortical plasticity.Brain Res Rev59347373
8. Paoletti P, Vergnano AM, Barbour B, Casado M (2009) Zinc at glutamatergic synapses. NSC 158: 126–136.P. PaolettiAM VergnanoB. BarbourM. Casado2009Zinc at glutamatergic synapses.NSC158126136
9. Deshpande A, Kawai H, Metherate R, Glabe CG, Busciglio J (2009) A Role for Synaptic Zinc in Activity-Dependent A Oligomer Formation and Accumulation at Excitatory Synapses. J Neurosci 29: 4004–4015.A. DeshpandeH. KawaiR. MetherateCG GlabeJ. Busciglio2009A Role for Synaptic Zinc in Activity-Dependent A Oligomer Formation and Accumulation at Excitatory Synapses.J Neurosci2940044015
10. Adlard PA, Cherny RA, Finkelstein DI, Gautier E, Robb E, et al. (2008) Rapid restoration of cognition in Alzheimer's transgenic mice with 8-hydroxy quinoline analogs is associated with decreased interstitial Abeta. Neuron 59: 43–55.PA AdlardRA ChernyDI FinkelsteinE. GautierE. Robb2008Rapid restoration of cognition in Alzheimer's transgenic mice with 8-hydroxy quinoline analogs is associated with decreased interstitial Abeta.Neuron594355
11. Faux NG, Ritchie CW, Gunn A, Rembach A, Tsatsanis A, et al. (2010) PBT2 rapidly improves cognition in Alzheimer's Disease: additional phase II analyses. J Alzheimers Dis 20: 509–516.NG FauxCW RitchieA. GunnA. RembachA. Tsatsanis2010PBT2 rapidly improves cognition in Alzheimer's Disease: additional phase II analyses.J Alzheimers Dis20509516
12. Lannfelt L, Blennow K, Zetterberg H, Batsman S, Ames D, et al. (2008) Safety, efficacy, and biomarker findings of PBT2 in targeting Abeta as a modifying therapy for Alzheimer's disease: a phase IIa, double-blind, randomised, placebo-controlled trial. Lancet Neurol 7: 779–786.L. LannfeltK. BlennowH. ZetterbergS. BatsmanD. Ames2008Safety, efficacy, and biomarker findings of PBT2 in targeting Abeta as a modifying therapy for Alzheimer's disease: a phase IIa, double-blind, randomised, placebo-controlled trial.Lancet Neurol7779786
13. Glaser EM, Van der Loos H (1981) Analysis of thick brain sections by obverse-reverse computer microscopy: application of a new, high clarity Golgi-Nissl stain. J Neurosci Methods 4: 117–125.EM GlaserH. Van der Loos1981Analysis of thick brain sections by obverse-reverse computer microscopy: application of a new, high clarity Golgi-Nissl stain.J Neurosci Methods4117125
14. Adlard PA, Parncutt JM, Finkelstein DI, Bush AI (2010) Cognitive loss in zinc transporter-3 knock-out mice: a phenocopy for the synaptic and memory deficits of Alzheimer's disease? J Neurosci 30: 1631–1636.PA AdlardJM ParncuttDI FinkelsteinAI Bush2010Cognitive loss in zinc transporter-3 knock-out mice: a phenocopy for the synaptic and memory deficits of Alzheimer's disease?J Neurosci3016311636
15. Bottomley GA, Clark IJ, Creaser II, Engelhardt LM, Geue RJ, et al. (1994) The synthesis and structure of encapsulating ligands: Properties of bicyclic hexamines. Aust J Chem 47: 143–179.GA BottomleyIJ ClarkII CreaserLM EngelhardtRJ Geue1994The synthesis and structure of encapsulating ligands: Properties of bicyclic hexamines.Aust J Chem47143179
16. Alpár A, Ueberham U, Brückner MK, Seeger G, Arendt T, et al. (2006) Different dendrite and dendritic spine alterations in basal and apical arbors in mutant human amyloid precursor protein transgenic mice. Brain Res 1099: 189–198.A. AlpárU. UeberhamMK BrücknerG. SeegerT. Arendt2006Different dendrite and dendritic spine alterations in basal and apical arbors in mutant human amyloid precursor protein transgenic mice.Brain Res1099189198
17. Jacobsen JS, Wu C-C, Redwine JM, Comery TA, Arias R, et al. (2006) Early-onset behavioral and synaptic deficits in a mouse model of Alzheimer's disease. Proc Natl Acad Sci USA 103: 5161–5166.JS JacobsenC-C WuJM RedwineTA ComeryR. Arias2006Early-onset behavioral and synaptic deficits in a mouse model of Alzheimer's disease.Proc Natl Acad Sci USA10351615166
18. Catala I, Ferrer I, Galofre E, Fabregues I (1988) Decreased numbers of dendritic spines on cortical pyramidal neurons in dementia. A quantitative Golgi study on biopsy samples. Hum Neurobiol 6: 255–259.I. CatalaI. FerrerE. GalofreI. Fabregues1988Decreased numbers of dendritic spines on cortical pyramidal neurons in dementia. A quantitative Golgi study on biopsy samples.Hum Neurobiol6255259
19. Davies CA, Mann DM, Sumpter PQ, Yates PO (1987) A quantitative morphometric analysis of the neuronal and synaptic content of the frontal and temporal cortex in patients with Alzheimer's disease. J Neurol Sci 78: 151–164.CA DaviesDM MannPQ SumpterPO Yates1987A quantitative morphometric analysis of the neuronal and synaptic content of the frontal and temporal cortex in patients with Alzheimer's disease.J Neurol Sci78151164
20. de Ruiter JP, Uylings HB (1987) Morphometric and dendritic analysis of fascia dentata granule cells in human aging and senile dementia. Brain Res 402: 217–229.JP de RuiterHB Uylings1987Morphometric and dendritic analysis of fascia dentata granule cells in human aging and senile dementia.Brain Res402217229
21. Alvarez VA, Ridenour DA, Sabatini BL (2007) Distinct Structural and Ionotropic Roles of NMDA Receptors in Controlling Spine and Synapse Stability. J Neurosci 27: 7365–7376.VA AlvarezDA RidenourBL Sabatini2007Distinct Structural and Ionotropic Roles of NMDA Receptors in Controlling Spine and Synapse Stability.J Neurosci2773657376
22. Bhatt DH, Zhang S, Gan W-B (2009) Dendritic Spine Dynamics. Annu Rev Physiol 71: 261–282.DH BhattS. ZhangW-B Gan2009Dendritic Spine Dynamics.Annu Rev Physiol71261282
23. Fischer M, Kaech S, Wagner U, Brinkhaus H, Matus A (2000) Glutamate receptors regulate actin-based plasticity in dendritic spines. Nat Neurosci 3: 887–894.M. FischerS. KaechU. WagnerH. BrinkhausA. Matus2000Glutamate receptors regulate actin-based plasticity in dendritic spines.Nat Neurosci3887894
24. Lisman J, Schulman H, Cline H (2002) The molecular basis of CaMKII function in synaptic and behavioural memory. Nat Rev Neurosci 3: 175–190.J. LismanH. SchulmanH. Cline2002The molecular basis of CaMKII function in synaptic and behavioural memory.Nat Rev Neurosci3175190
25. Merrill MA, Chen Y, Strack S, Hell JW (2005) Activity-driven postsynaptic translocation of CaMKII. Trends Pharmacol Sci 26: 645–653.MA MerrillY. ChenS. StrackJW Hell2005Activity-driven postsynaptic translocation of CaMKII.Trends Pharmacol Sci26645653
26. Pratt KG, Watt AJ, Griffith LC, Nelson SB, Turrigiano GG (2003) Activity-dependent remodeling of presynaptic inputs by postsynaptic expression of activated CaMKII. Neuron 39: 269–281.KG PrattAJ WattLC GriffithSB NelsonGG Turrigiano2003Activity-dependent remodeling of presynaptic inputs by postsynaptic expression of activated CaMKII.Neuron39269281
27. Engert F, Bonhoeffer T (1999) Dendritic spine changes associated with hippocampal long-term synaptic plasticity. Nature 399: 66–70.F. EngertT. Bonhoeffer1999Dendritic spine changes associated with hippocampal long-term synaptic plasticity.Nature3996670
28. Jourdain P, Fukunaga K, Muller D (2003) Calcium/calmodulin-dependent protein kinase II contributes to activity-dependent filopodia growth and spine formation. J Neurosci 23: 10645–10649.P. JourdainK. FukunagaD. Muller2003Calcium/calmodulin-dependent protein kinase II contributes to activity-dependent filopodia growth and spine formation.J Neurosci231064510649
29. Maletic-Savatic M, Malinow R, Svoboda K (1999) Rapid dendritic morphogenesis in CA1 hippocampal dendrites induced by synaptic activity. Science 283: 1923–1927.M. Maletic-SavaticR. MalinowK. Svoboda1999Rapid dendritic morphogenesis in CA1 hippocampal dendrites induced by synaptic activity.Science28319231927
30. Matsuzaki M, Honkura N, Ellis-Davies GCR, Kasai H (2004) Structural basis of long-term potentiation in single dendritic spines. Nature 429: 761–766.M. MatsuzakiN. HonkuraGCR Ellis-DaviesH. Kasai2004Structural basis of long-term potentiation in single dendritic spines.Nature429761766
31. Nägerl UV, Eberhorn N, Cambridge SB, Bonhoeffer T (2004) Bidirectional activity-dependent morphological plasticity in hippocampal neurons. Neuron 44: 759–767.UV NägerlN. EberhornSB CambridgeT. Bonhoeffer2004Bidirectional activity-dependent morphological plasticity in hippocampal neurons.Neuron44759767
32. Otmakhov N, Tao-Cheng J-H, Carpenter S, Asrican B, Dosemeci A, et al. (2004) Persistent accumulation of calcium/calmodulin-dependent protein kinase II in dendritic spines after induction of NMDA receptor-dependent chemical long-term potentiation. J Neurosci 24: 9324–9331.N. OtmakhovJ-H Tao-ChengS. CarpenterB. AsricanA. Dosemeci2004Persistent accumulation of calcium/calmodulin-dependent protein kinase II in dendritic spines after induction of NMDA receptor-dependent chemical long-term potentiation.J Neurosci2493249331
33. Shimada A, Mason CA, Morrison ME (1998) TrkB signaling modulates spine density and morphology independent of dendrite structure in cultured neonatal Purkinje cells. J Neurosci 18: 8559–8570.A. ShimadaCA MasonME Morrison1998TrkB signaling modulates spine density and morphology independent of dendrite structure in cultured neonatal Purkinje cells.J Neurosci1885598570
34. Adlard PA, Bush AI (2006) Metals and Alzheimer's disease. J Alzheimers Dis 10: 145–163.PA AdlardAI Bush2006Metals and Alzheimer's disease.J Alzheimers Dis10145163
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
© 2011 Adlard et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License: https://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Abstract
We have previously demonstrated that brief treatment of APP transgenic mice with metal ionophores (PBT2, Prana Biotechnology) rapidly and markedly improves learning and memory. To understand the potential mechanisms of action underlying this phenomenon we examined hippocampal dendritic spine density, and the levels of key proteins involved in learning and memory, in young (4 months) and old (14 months) female Tg2576 mice following brief (11 days) oral treatment with PBT2 (30 mg/kg/d). Transgenic mice exhibited deficits in spine density compared to littermate controls that were significantly rescued by PBT2 treatment in both the young (+17%, p<0.001) and old (+32%, p<0.001) animals. There was no effect of PBT2 on spine density in the control animals. In the transgenic animals, PBT2 treatment also resulted in significant increases in brain levels of CamKII (+57%, p = 0.005), spinophilin (+37%, p = 0.04), NMDAR1A (+126%, p = 0.02), NMDAR2A (+70%, p = 0.05), pro-BDNF (+19%, p = 0.02) and BDNF (+19%, p = 0.04). While PBT2-treatment did not significantly alter neurite-length in vivo, it did increase neurite outgrowth (+200%, p = 0.006) in cultured cells, and this was abolished by co-incubation with the transition metal chelator, diamsar. These data suggest that PBT2 may affect multiple aspects of snaptic health/efficacy. In Alzheimer's disease therefore, PBT2 may restore the uptake of physiological metal ions trapped within extracellular β-amyloid aggregates that then induce biochemical and anatomical changes to improve cognitive function.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer