Abstract
Several animal models of Alzheimer’s disease have been used in laboratory experiments. Intrahippocampal injection of fibrillar amyloid-beta (fAβ) peptide represents one of the most frequently used models, mimicking Aβ deposits in the brain. In our experiment synthetic fAβ1–42 peptide was administered to rat hippocampus. The effect of the Aβ peptide on spatial memory and dendritic spine density was studied. The fAβ1–42-treated rats showed decreased spatial learning ability measured in Morris water maze (MWM). Simultaneously, fAβ1–42 caused a significant reduction of the dendritic spine density in the rat hippocampus CA1 region. The decrease of learning ability and the loss of spine density were in good correlation. Our results prove that both methods (MWM and dendritic spine density measurement) are suitable for studying Aβ-triggered neurodegeneration processes.
1. Introduction
Alzheimer’s disease (AD) is a progressive neurodegenerative disorder characterized by deficit of learning process, severe memory loss, and complex behavioural changes [1–5]. Neuropathological hallmarks of AD include the cerebral accumulation of extracellular senile plaques containing various forms of amyloid-beta (Aβ) peptide assemblies and the presence of intracellular neurofibrillary tangles containing tau protein [6–8]. Other features of AD are neuroinflammation, cerebrovascular alterations, activated astrocytes, and microglia as well as synaptic and neuronal loss in specific brain regions [9–11]. The affected brain regions are forebrain and medial temporal lobe structures like the hippocampus (HC), the entorhinal cortex, and the amygdala [11]. Synapse loss is strongly correlated with cognitive impairment; thus synapse number is the best indicator of cognitive decline in AD [1, 12]. The senile plaques are associated with local synapse and dendritic spine loss [13, 14]. Moreover, the fibrillar deposits are surrounded by a halo of oligomeric Aβ assemblies [15]. Extracellular oligomeric Aβ associates with dendritic spines covering their surface [15]. In addition, intracellular Aβ may also contribute to AD pathology by tau hyperphosphorylation and synaptic dysfunction [16]. The toxic effects of different aggregation forms of Aβ (oligomers, protofibrils, and fibrils) have not been revealed completely yet.
Dendritic spines are cellular compartments containing the molecular machinery important for synaptic transmission and plasticity [17]. In pyramidal neurons of the hippocampus, there is an almost one-to-one relationship between the number of dendritic spines and excitatory synapses [17, 18]. The loss of dendritic spines and the presence of dystrophic neurites have been reported both in the amyloid precursor protein (APP) overexpressing transgenic mouse model of AD and in the AD-affected human brain [2, 8, 19, 20]. The spine density of prefrontal cortex neurons is greatly reduced in aged monkeys as a hallmark of cognitive decline [21]. Neurocortical pyramidal neurons have extensive apical and basilar dendritic trees to integrate information from excitatory and inhibitory synaptic inputs. In the neuronal network, dendritic spines represent the principal receptive sites for the excitatory inputs to the neurons. The strength, stability, and function of the excitatory synaptic connections constitute the basis of cognitive function [22]. In the cerebral cortex of mammals, the rapid synaptogenesis during early postnatal life is followed by a substantial loss of synapses/spines that extends through adolescence. In adulthood, the number of spines remains relatively stable and then decreases progressively with aging [22, 23]. Spines appear and disappear through life, but their turnover rate declines with the age and is regulated by the neuronal activity [18]. Dendritic spines undergo structural modifications when the synaptic strength is experimentally modified (e.g., by evoking long-term potentiation or long-term depression) [18, 22, 24].
Extracellular delivery of Aβ peptides can initiate synaptic loss in rodent brains [25]. Intrahippocampal (IHC) administration of Aβ is a widely used animal model to study AD [4, 25–38]. The injection of Aβ into murine brain rapidly establishes the symptoms of AD. This method is suitable for studying the effects of the different aggregates of Aβ. There are conflicting results about the neurotoxicity of β-amyloid plaque depositions [39]; however, the toxic effect of Aβ peptides on synapses has been widely acknowledged.
Reduction of dendritic spine density has been shown in cell cultures after Aβ treatment [40–43]. Furthermore, IHC administration of fibrillar Aβ1–40 has been shown to decrease spine density [25, 28]. Interestingly, no experiments have been performed using well characterized Aβ1–42, the most toxic form of Aβ peptides. Thus the aim of this study was to assess the impact of fibrillar Aβ1–42 (fAβ1–42) administration on spatial memory of rats and dendritic spine density in the hippocampus. Our hypothesis was that IHC injected synthetic, fibrillar form of Aβ1–42 could simultaneously influence and reduce the learning process and dendritic spine density. Since hippocampal dendritic spines are the key elements in acquisition and retention and have been implicated in learning and memory processes [44, 45], we also compared the correlation between the changes of dendritic spine density (induced by fAβ1–42 administration) and the spatial memory of rats.
2. Materials and Methods
2.1. Animals
Male Charles-River Wistar rats (), weighing about 210–230 g at the beginning of the experiment, were used as subjects. Two groups, control () and fAβ1–42-treated (), were formed. They were housed in groups of three under constant temperature, humidity, and lighting conditions (23°C, 12 : 12 h light/dark cycle, lights on at 7 a.m.). Standard rat chow and tap water were supplied ad libitum. All behavioural procedures were conducted during the light phase. Handling was done daily at the same time. Experiments were performed in accordance with the European Communities Council Directive of 22 September 2010 (2010/63/EU on the protection of animals used for scientific purposes). Formal approval to conduct the experiments was obtained from the Animal Experimentation Committee of the University of Szeged.
2.2. Synthesis of Aβ1–42 and Preparation of the Fibrillar Peptide Aggregates
The synthesis was performed as reported earlier in Bozso et al. [46]. The fAβ1–42 was prepared as described by He et al. [4]. Briefly, Aβ1–42 was dissolved in hexafluoroisopropanol (HFIP, Sigma Aldrich) to 1 mM; HFIP was removed in vacuo. The peptide was suspended to make a 5 mM solution in dimethyl sulfoxide (DMSO, Sigma Aldrich). The fibrillar form was prepared diluting the DMSO stock solution of the peptide with a 100 mM HEPES buffer to a final concentration of 222 μM. The solution was incubated at 37°C for 7 days. After the aggregation period the sample was centrifuged for 10 min at 15000 g at room temperature. The pellet containing the freshly prepared fibrillar Aβ1–42 was resuspended in 100 mM HEPES buffer (pH 7.5) and used in the experiment. The samples containing Aβ fibrils were characterized by transmission electron microscope (Philips CM10, FEI, Eindhoven, Figure 1).
2.3. Surgery
Rats were anaesthetized with an intraperitoneal injection of a mixture of ketamine (10.0 mg/0.1 kg) and xylasine (0.8 mg/0.1 kg). The animals were then placed in a stereotaxic apparatus, a midline incision of the scalp was made, the skin and muscles were carefully retracted to expose the skull, and a hole was drilled above the target area. The solution was injected with a Hamilton syringe into the right HC unilaterally at a rate of 1.0 μL/min, beginning 2 min after the needle was lowered. The needle was removed very slowly 2 min after the end of injection. The following coordinates were used (from Bregma point): AP: −3.6; ML: −2.4; DV: −2.8 [47]. Rats were randomly injected either with the fibrillar form of Aβ1–42 (222 μM Aβ1–42) or with vehiculum (physiological saline). The Aβ1–42-injected and the control animals were treated with antibiotics and analgesics after the surgery.
2.4. Spatial Navigation in the Morris Water Maze
Spatial learning and memory were assessed in a Morris water maze (MWM) on days 14 to 20 after IHC fAβ1–42 administration. Behavioural testing was carried out in a room illuminated by three lamps giving diffuse light of approximately equal intensity at all points of the maze. The maze consisted of a circular pool ( = 180 cm, = 60 cm) filled with water (°C) and made opaque with milk. A black curtain was positioned around the pool with distal cues. A video camera was mounted on the ceiling directly above the test apparatus and relied to a video tracking system. The behaviour of the animals was automatically recorded with the software EthoVision 2.3 (Noldus Information Technology, The Netherlands, 2002).
Memory acquisition trials (training period) were performed daily during the light phase, in blocks of 4, for 6 days [4]. The pool was divided into four virtual quadrants, and an invisible escape platform (diameter: 10 cm) was submerged in the middle of one of the four quadrants 1.5 cm below the water surface. At each trial, the rats were allowed to swim freely for a maximum of 120 sec until they found the platform and were then allowed to stay on it for 10 sec. If the rat failed to find the platform within 120 sec, it was guided to or was placed on the island manually for 10 sec. During the acquisition period, four different starting points were used and the starting positions were varied pseudorandomly over the trials. Twenty-four hours after the last acquisition trial, retention was assessed in a 120 sec probe trial, with the platform removed.
The data recorded by video tracking were used to calculate the time to reach the platform, swim speed, and swim path length (distance) during acquisition trials as well as percent time spent in each of the 4 virtual quadrants and time spent and number of crossings over the platform’s position during the probe test.
2.5. Quantification of Dendritic Spine Density Using Golgi Impregnation
FD Rapid GolgiStain Kit (FD NeuroTechnologies, Consulting & Services, Inc., USA) was used according to the manufacturers’ instructions. Rats (, 3 per group) were deeply anesthetized before the brain was removed from the skull. The sacrificing was made after 29 days of the IHC injection. The brains were removed quickly and handled carefully to avoid damage of the tissue, and then tissue blocks including hippocampus (approximately 0.7-0.8 cm) were cut from the brain. The tissue blocks were immersed in the impregnation solution (A + B solution) and stored at room temperature for 2 weeks in the dark. After the first impregnation period the brains were transferred into the second solution (C) and stored at 4°C in the dark for at least 48 hours.
100 μm coronal sections were cut with a vibration microtome (Zeiss Microm HM 650 V) and were mounted on gelatin coated glass slides. After the staining procedure (D, E solution) and dehydration, the slides were coverslipped with DPX mountant for histology (VWR International).
2.6. Quantitative Analysis
The Golgi sections were studied by inverse light microscopy, using oil immersion objectives. A total of 25 pyramidal neurons from the dorsoventral hippocampal CA1 (stratum radiatum) were studied from each of the 6 animals (75 dendritic shafts per group were analyzed). The spine density of the proximal apical dendrite area was analyzed (minimum 100 μm from soma). For each examined neuron, one 100 μm long segment from a second- or third-order dendrite (protruding from its parent apical dendrite) was chosen for spine density quantification as previously described [48]. The dendrites were selected under a 100x oil immersion lens and the images of these apical dendrites were captured through a camera (AxioCam MRC V5, program: AxioVision 40 V. 4.8.1.0 Carl Zeiss Imaging Solutions GmbH) connected to a light microscope (Zeiss Observer Z1, with 10x ocular magnification) and a computer. Serial images were made from each dendrite in the whole of the analyzed segment (Z-stack). The captured multiple photomicrographs from one dendrite were then stacked into one file. To stack the images and determine the spine density, ImageJ 1.44 software (National Institute of Health, Bethesda, USA) was used.
2.7. Statistical Analysis
Behavioural data were analyzed by repeated measures ANOVA, followed by Fisher’s LSD post hoc tests for multiple comparisons. For the evaluation of the results of Golgi impregnation, Student’s -test for independent samples was used. Statistical significance was set at . The data were expressed as the means ± (S.E.M.).
3. Results
3.1. Spatial Learning and Memory in the Morris Water Maze
MWM was used to test spatial learning and memory each day on days 14 to 20 after IHC administration of fAβ1–42. Escape latency to find the platform was used as a measure for evaluating spatial memory. The results showed that the performance of both groups (fAβ-treated and untreated) improved from day to day, reflecting long-term memory. However, learning was slower each day in the fAβ1–42-treated compared to the control group: escape latencies were significantly longer in rats with fAβ1–42 treatment than in the control animals analysed by repeated measures ANOVA (; ) (Figure 2(a)). A significant difference was observed between the groups also for swimming distance (repeated measures ANOVA: ; ) (Figure 2(b)).
(a)
(b)
Despite the significantly slower learning in the fAβ1–42-treated group, performance at the probe test (given 24 h after the learning phase) indicated that spatial memory was not impaired, as the time spent in quadrants and the number of crossings over the virtual platform’s position were comparable in the two groups (; and ; , resp.) (Figures 3(a) and 3(b)).
(a)
(b)
3.2. Dendritic Spine Density
The Golgi staining method labelled a subset of neurons in the hippocampus. In general, 20–30 fully impregnated CA1 pyramidal cells could be detected per slice. There was no difference between the groups in staining.
We investigated all types of spines but solely focused on determining dendritic spine density. Spine numerical density was different between the two groups (; ). In the fAβ1–42-treated group decreasing spine density (spine number) was detected compared to the controls (Figure 4). Each column represents the mean value of the dendritic spine number of 75-75 pyramidal neurons.
Photomicrographs of the pyramidal neurons from control, nontreated rats (Figures 5(a) and 6), and fAβ1–42-treated rats (Figures 5(b) and 7) clearly demonstrate the difference in dendritic spine density in the two experimental groups.
(a)
(b)
(a)
(b)
(c)
(a)
(b)
(c)
4. Discussion
The present study explored the effects of fAβ1–42 on spatial behaviour and on hippocampal dendritic spines in nontransgenic rats. Aβ accumulation in the specific brain regions is a hallmark of AD pathology; however, the role of amyloid plaques has been debated. Depositions of fAβ in plaques and the surrounding oligomeric Aβ are considered as trigger signals to induce dendritic spine loss and synapse dysfunction in AD. Aβ assemblies are synaptotoxic: they can be bound to axons and membrane proteins, resulting in Ca2+ influx into the neurons [49]. The synapse and dendritic spine loss are strongly correlated with cognitive impairment in AD, and Aβ has been shown to target synapses [40, 50].
Numerous studies have reported significant changes after IHC administration of various types and aggregation forms of Aβ [4, 25–38]. Some studies reported that synapse dysfunction was triggered by Aβ oligomers [49, 51]. Other studies proposed fAβ deposits as causative factor for the local synaptic abnormalities since decrease of dendritic spine density was detected nearby the Aβ plaques [13, 52–54]. However, it has not been clear how the nondiffusible, immobile Aβ fibrils interact with neuronal structure. As of today, senile plaques are considered mostly as nontoxic “outburns” sequestering toxic Aβ species to nontoxic fibrils. However, bilateral IHC injection of fAβ1–42 results in reduction of neuronal density and increases of glial fibrillary acidic protein intensity, with simultaneous appearance of numerous Aβ deposits and behavioural performance deficits [4, 26]. IHC administration of shorter form of Aβ (Aβ1–40) results in decreased density of dendritic spines in hippocampus [25, 28].
Our current findings demonstrated that synthetic fAβ1–42 simultaneously decreased spatial learning ability measured in MWM (Figure 2(a)) and reduced dendritic spine density in the rat hippocampus CA1 region (Figures 4–6). According to the literature data, the synthetic fAβ assemblies have also a surrounding of Aβ oligomers [55], in accordance with the law of chemical equilibriums. After fAβ injection, diffusible Aβ oligomers could be formed in the rat hippocampus and initiate dendritic spine density loss. The measured spine loss in HC CA1 region may explain the decreased learning ability since the presence and maturation of dendritic spines on the CA1 pyramidal cells are necessary to evolve the spatial memory unit [56]. It is generally accepted that misfolded proteins initiate dendritic spine reduction and memory decline. Aβ and α-synuclein oligomers decrease the amount of synaptic proteins and vesicles and via tau hyperphosphorylation initiate the loss of dendritic spines [57, 58]. The instability of dendritic spines leads to progressive neocortical spine loss in a mouse model of Huntington’s disease [59]. Our results support the theory that decreasing spine density in AD can cause or contribute to the memory decline: dendritic spines are the site of most excitatory synapses and their loss is in good correlation with the cognitive dysfunction.
Abbreviations
| AD: | Alzheimer’s disease |
| APP: | Amyloid precursor protein |
| Aβ: | Amyloid-beta |
| DMSO: | Dimethyl sulfoxide |
| fAβ142: | Fibrillar Aβ142 |
| HC: | Hippocampus |
| HFIP: | Hexafluoroisopropanol |
| IHC: | Intrahippocampal |
| MWM: | Morris water maze. |
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Authors’ Contribution
Emőke Borbély and János Horváth contributed equally to this work.
Acknowledgments
The authors thank Zsuzsa Penke, Ph.D., for the helpful discussion and writing assistance and Titanilla Szögi for her technical assistance. This work was supported by the European Union Seventh Framework Programme Food Grant 211 696 (LipiDiDiet) as well as by the Hungarian research Grant TÁMOP 4.2.2/A-11/1/KONV-2012-0052.