Physical Exercise Enhances Neuroplasticity and Delays Alzheimer’s Disease

Behavior level – learning and memory function

A growing number of studies support the idea that physical exercise increases brain function throughout life [11, 12]. In a meta-analysis that included a total of 59 studies (from 1947 to 2009) examining the relationship between physical activity and academic achievement in school-age children, the authors demonstrated significant and positive correlations between physical activity and cognitive outcomes [13]. In another meta-analytic review of 29 randomized controlled trials examining the association between aerobic exercise and neurocognitive performance in a group with a mean age of≥18 years of age, positive association between exercise with attention, processing speed, and executive and memory function was also evident [14]. Particularly, exercise enhances pattern separation in humans, which is defined as a process to remove redundancy from similar input patterns so that events can be separated from each other and interference can be minimized [15]. An acute bout of moderate intensity aerobic exercise improves the pattern separation in young adults [16]. This mnemonic discrimination ability is highly correlated with aerobic fitness. The higher fitness group (i.e., high endurance capacity during exercise) had better performance in the pattern separation test compared with the lower fitness group [17]. The memory-enhancing effect of exercise on young adults has also been demonstrated in a series of hippocampal-associated learning and memory tests designed for rodents. Almost all young animal studies confirmed the memory-facilitating effect (i.e., acquisition and retention) of exercise. These tests included novel object recognition [18, 19], object displacement [19], Morris water maze [18, 20–22], radial arm water maze [23], Y-maze [24], passive avoidance [25, 26] and contextual fear conditioning [27–29].

In addition to benefiting healthy young adults, physical exercise is known to delay age-related cognitive decline. A randomized, controlled trial study that evaluated the association between exercise and cognitive function in 120 healthy participants aged over 65 showed that 6 months of exercise reversed age-related loss in hippocampus volume and improved performance in a computerized spatial memory task [30]. A meta-analysis including 42 studies (from 1966 and 2010) of cognitive interventions of exercise in 3,781 healthy older adults aged 55 and older concluded that aerobic fitness training improves cognitive performance [31]. Similar findings have also been obtained in aged animals. For example, it has been shown that 6-weeks of treadmill exercise ameliorates age-induced losses in short-term (tested by step-down avoidance task) and long-term memory (tested by radial 8-arm maze) functions in 24-month-old rats [32]. Another study demonstrated that one week of mild treadmill exercise was enough to improve spatial learning and memory ability, which was tested by the Morris water maze in 23-month-old rats [33]. These results suggest that exercise not only enhances learning and memory in young adults but also protects aged individuals from age-related cognitive impairment.

Although the beneficial effects of exercise on learning and memory have been well-documented in numerous studies, some studies of rodents failed to find such an association. This discrepancy may be due to the different exercise intensities and durations employed in each study. For example, high levels of running exercise are known to impair hippocampus-dependent spatial memory [34, 35] and other types of memory [36]. It has been speculated that the exercise intensity affects cognitive performance in a reversed U-shaped fashion. In other words, cognition improvement is most effective at moderate-intensity exercise, whereas exercise at low-intensity is less effective and at high-intensity would induce high levels of stress responses, hence impairing cognitive performance [37, 38].

Behavior level – mental function

The beneficial effects of exercise extend beyond cognitive function. A plethora of evidence supports the notion that exercise can prevent or delay the onset of various mental disorders such as anxiety, depression, and posttraumatic stress disorder [39, 40]. Several meta-analysis studies suggest that exercise could reduce depressive and anxiolytic symptoms in adolescents with clinical levels of mental illness [41, 42]. The effects of exercise on mental health are dose-dependent. In adults, a moderate amount of exercise exerts greater benefits in the mental health than low or high doses of exercise [43].

The positive effects of exercise on mood disorders have been examined in various animal models. It has been shown that a 2-week period of treadmill exercise effectively decreased anxiety-like (tested by elevated plus maze) and depressive-like (tested by sucrose preference test) behaviors in a single-prolonged stress-induced post-traumatic stress disorder rat model [44]. Besides stress, mood disorders commonly occur secondary to medical conditions such as obesity and stroke. In high-fat diet induced obesity, and middle cerebral artery occlusion-induced stroke animal models, exercise was also capable of attenuating depression- and anxiety-like behaviors in the modeled animals [45, 46].

Behavior level – motor function

Exercise has a profound effect on motor function. It has been demonstrated that a single session of exercise not only significantly improves performance in a motor learning task during the training session [47] but also leads to longer retention of said motor skills than the control group. This is especially clear when motor memory is assessed one day after practice [48]. In the animal studies, both wheel and treadmill exercise enhanced animals’ motor performance in foot fault-placing and parallel bar-crossing, as well as the staircase reaching task [49], rota-rod test [50], beam walking and cylinder tests [51], and ladder-climbing tests [52], after ischemic or hemorrhagic stroke. Furthermore, wheel-running and treadmill exercise can also rescue motor behaviors (e.g., rotarod performance test, rotational behavior test, ladder rung walking task, and gait parameters) that are impaired by different dopamine-depletion methods such as LPS, 6-OHDA and MPTP [53–55].

Cellular level – neurons

Neuroplasticity is a continuous process that modifies existing neural networks by mediating structural and functional adaptations of synapses in response to changes in behavior. Exercise-induced structural and functional changes in the brain have been reported in both human and animal studies.

Cellular level – glial cells

In parallel with the effects of exercise on neurons, exercise is also known to have multiple effects on glial cells. Astrocytes, the major glial cells in the brain, play a vital role in the regulation of brain energy transmissions from the vasculatures to the neurons [88, 89]. Because proper and efficient astrocyte function is essential for supporting neuronal function [88], it has been suggested that exercise-induced enhancement of neuronal function may occur via the adaptation of astrocyte behavior. Exercise induces widespread plasticity in astrocytes [90]. It has been shown that one month of treadmill exercise increases GFAP-labeled cell numbers and the improvement of astrocyte plasticity in the CA1 area [91]. Furthermore, immunostaining signals of S100β and aquaporin-4, two astrocyte-specific markers, in various brain regions related with cognitive function, such as the hippocampus, medial prefrontal cortex, and orbitofrontal cortex, increased after 12 days of wheel-running in rats [90]. In mice, 4 weeks of physical exercise (a combination of treadmill and running wheel) increased the average length and the area enclosed by each astrocytic projection in the hippocampus [92]. The exercise also changed the orientation of astrocytic projections towards DG in the hippocampus, the region with significant increase in neurogenesis following the exercise [92].

The structure and function of microglia, the major immune cells in the central nervous system, are also affected by exercise. Exercise has been reported to decrease the aging-induced activation and proliferation of microglia in the hippocampus [93, 94]. In parallel to the in vivo findings, microglia isolated from aged rodents that participated in chronic wheel-running exercise have a lower basal level of IL-1β and TNF-α when compared to the microglia isolated from their sedentary littermates [95–97]. Similarly, when stimulating these microglia with LPS, the production of IL-1β was also lower in the chronic wheel-running group. In addition to the inflammatory cytokines, neuron-microglia contact signaling, an important regulator of microglial activation, is affected by exercise. For example, CX3CL1 and CD200 are immunomodulatory factors expressed by neurons to inhibit microglial activation through binding with the CX3CL1 and CD200 receptor on microglia, respectively [98]. Chronic exercise is known to upregulate the expression of the CX3CL1 gene [99] and the CD200/CD200R proteins in the brain [100], supporting that exercise may inhibit microglial activation via the enhancement of neuron-microglia contact signaling.

Molecular level – brain-derived neurotrophic factor (BDNF)

The mechanisms underlying exercise-induced neuroplasticity involve, at least in part, several neurotrophic and growth factors. Among them, BDNF is a well-characterized mediator of neuronal growth [101], plasticity [102, 103], and survival [99]. Human and animal studies collectively suggest that exercise is an active strategy to upregulate the expression of BDNF, which plays an essential role in exercise-induced neuroplasticity [104, 105]. Different types of exercise (i.e., voluntary wheel-running and mandatory treadmill running) all seem to be capable of enhancing the production of BDNF in the hippocampus of young and aged animals [22, 28, 106–108]. It is believed that BDNF binds to its receptor, tropomyosin receptor kinase B (TrkB), which increases the phosphorylation levels of cAMP response-element-binding (CREB) and the translation of synaptic-plasticity related proteins [22, 28, 103, 109, 110], and finally enhances neuroplasticity. It has been demonstrated that animals with higher levels of BDNF and TrkB receptor in the hippocampus exhibit better performance in radial water mazes [23] and passive avoidance tasks [26]. On the contrary, blocking the TrkB receptor with a TrkB receptor-IgG chimera or antagonist inhibits the efficacy of exercise-induced upregulation of synaptic plasticity-related proteins significantly [103, 109], resulting in a disruption of benefits on cognitive function. Behavior tests in the Morris water maze, passive avoidance, and contextual fear condition also suggest that the learning and memory abilities enhanced by exercise are reduced to sedentary levels after treating the animals with TrkB receptor blockers [26, 28, 111].

Molecular level – insulin-like growth factor 1 (IGF-1)

IGF-1 is also a key modulator of neuronal functions in the central nervous system, including synaptic plasticity, synapse density, neurotransmission, neurogenesis and neuron differentiation [112–114]. Chronic exercise-enhanced adult hippocampal neurogenesis, learning, and memory performance have been attributed to IGF-1 signaling in the hippocampus [115–117]. The levels of IGF-1 in the blood positively correlated with the time animals spent in the target quadrant during the probe trial of the Morris water maze [115]. The levels of IGF-1 in the brain are also increased after exercise, which is a result of uptake in circulating IGF-1 [118]. Infusion of anti-IGF-I antiserum or neutralization of hippocampal IGF-1 receptor inhibits the exercise-induced brain uptake of circulating IGF-I, disrupts neurogenesis, and lessens the effects of exercise on memory retention [116, 117, 119]. Exercise-induced upregulation of BDNF may be partially affected by the IGF-1 pathway. Blockade of the IGF-I receptor during exercise inhibits the ability of exercise to enhance the expressions of pro-BDNF and BDNF in the hippocampus [119].

Molecular level – vascular endothelial growth factor (VEGF)

VEGF, an angiogenic protein, is known to have neuroprotective and neurotrophic functions [120]. VEGF can be synthesized and released by peripheral vascular endothelial cells and brain cells, including astrocytes, ependymal cells, and neuronal stem cells [121]. Intracerebroventricular injection of VEGF or gene transfer of VEGF in the hippocampus increases the number of BrdU labeling cells in the subventricular zone and the subgranular zone of the DG, suggesting an intimate association between angiogenesis and neurogenesis [122, 123]. The changes in the vascular niche promotes local signaling that directly regulates or indirectly activates other regulatory factors to stimulate the proliferation, differentiation, and survival of newborn neurons [124]. Voluntary exercise is known to increase the expressions of VEGF receptors, fms-like tyrosine kinase (Flt-1/VEGF1), and fetal liver kinase (Flk-1 or VEGFR2) in the hippocampus [125]. The activation of the intracellular tyrosine kinase domains of the VEGF receptors induces the activation of several downstream signaling pathways which in turn enhances the proliferation of neuron precursors [126, 127]. Peripheral VEGF seems to play an essential role in exercise-induced adult hippocampal neurogenesis [128, 129]. Blockade of VEGF signaling by intravenous injection of adenoviruses carrying the chimeric VEGFR1 receptor or conditionally knocking down skeletal myofiber-specific VEGF gene nullifies running-induced adult hippocampal neurogenesis [128, 129].

Molecular level – nerve growth factor (NGF)

NGF also plays a role in promoting neuronal function, especially the survival of neural progenitors [130]. Results gathered from microarray and nuclease protection assays indicate that the expression of hippocampal NGF is increased after wheel- running, with a peak at 2 to 3 days after exercise [87, 131]. The expressions of hippocampal NGF and one of its receptors, tropomyosin receptor kinase A (TrkA), are increased after 8-weeks of treadmill running in rodents. Similar to BDNF/TrkB signaling, the binding of NGF to TrkA stimulates the downstream transcription factor, CREB, and induces various gene transcriptions related to cell survival and neuroplasticity [132].

Physical activity and aging

Aging is an irreversible and inescapable process. Age alone increases the risk of dementia and AD [133]. Even in the absence of overt disease symptom, increasing age is associated with decreasing cognitive function of varying severity in human beings. The hippocampus is considerably vulnerable to aging and is involved in the development of aging-related deficits of neuroplasticity and memory functions [134]. Aging-associated memory deficits are accompanied by abnormal structural and functional changes in the hippocampus. Aging also reduces hippocampus size, induces hippocampal neuron loss [135, 136], suppresses dendritic arbors and spine density of the hippocampal neurons [137–139], decreases the degrees of DG neurogenesis [140, 141], and represses the field excitatory postsynaptic potentials [142, 143] and LTP induction [144] in the hippocampus.

Several lines of evidence indicate that exercise can ameliorate the structural and functional changes in the brain during aging. In the pioneer study, Samorajski et al. showed that exercise (spontaneously wheel-running) significantly increased recent memory in the passive avoidance test in adults (10–14 month), middle-aged (20–24 month), and old (28–30 month) C57BL/6J male mice [145]. Later studies also demonstrated that physical activity increases the cognitive reserve and prevents aging-related memory decline [108, 146, 147]. Regular aerobic exercise increases the hippocampal volume by 2%, effectively countering age-related loss in volume in older adults (55–80 years old) without dementia [30]. Six-weeks of moderate treadmill training reverses the age-related declines in the complexity of dendritic arbors and the density of the dendritic spines of hippocampal CA1 pyramidal neurons in mice [139]. Furthermore, six-weeks of moderate-intensity running enhanced the LTP induced by high-frequency stimulation in the CA1 regions and hippocampal memory in mice of different ages, even when the memory impairment had progressed to an advanced stage [139]. It is widely accepted that exercise enhances the adult hippocampal neurogenesis that is critical for hippocampal memory functions [21, 148–150]. The decline in neurogenesis in aged (19 months of age) mice is reversed to 50% of young (3 months of age) control levels by 45-days of voluntary wheel-running [141]. Yang et al. demonstrated that the hippocampal neurogenesis dramatically decreased by the time mice reached nine months of age and 5-weeks of treadmill running attenuated the decrease of the number of neural stem/progenitor cells during aging and enhanced the maturation of newborn neurons [66].

Physical activity and AD – neuroprotection

It is well known that neurotrophic and growth factors (BDNF, IGF-1, VEGF, NGF) are attenuated in AD [151–154]. Therefore, one of the potential mechanisms for exercise to protect the brain against AD may be via the upregulations of neurotrophic and growth factors. In the following section, we will discuss exercise-induced neuroprotection against AD with focuses on the four trophic factors.

Both clinical and basic research documents that BDNF mRNA and proteins, including proBDNF, are severely decreased in AD, especially in the hippocampus [155–157]. Several lines of evidence have suggested that decreases in brain BDNF and NGF levels contribute to AD pathology [158, 159]. On the contrary, administration of lentiviral vectors to constitutively express BDNF in the hippocampus can prevent cell death, reverse neuronal atrophy, and ameliorate behavioral deficits, hence delaying the development of AD [160]. As a physiological approach to increase the production of neurotrophic factors, exercise has been reported to alleviate hippocampal functional impairment in AD through the induction of BDNF expression in the hippocampus [71, 105]. Exercise-induced BDNF signaling activation has been applied to a variety of AD models, including the Aβ injection-induced non-Tg AD model [161], APP/PS1 [71, 162], APOE4 [163], NSE/APPsw [164] and NSE/PS2 m [165, 166] Tg animal models. Increased BDNF signaling due to exercise is suggested to protect against AD-induced learning and memory deficits through enhancing neurogenesis [167] and LTP expression [161, 162], modulating dendritic morphology [71], and reversing Aβ-induced neurotoxicity [168].

Neurotrophic signaling not only directly enhances neuronal function but also decreases AD pathological burden. An in-vitro study suggests that APP processing shifts towards the non-amyloidogenic α-secretase pathway in response to BDNF treatment [169], which is known to reduce the production of Aβ_{1 - 40} and Aβ_{1 - 42}. Beyond amyloid pathology, BDNF also affects the tau pathology through mediating tau phosphorylation. In P19 neurons, BDNF stimulation induces a rapid decrease in tau phosphorylation [170]. The effects of BDNF on tau dephosphorylation is known to be TrkB dependent. TrkB activation induces AKT-dependent phosphorylation of GSK-3β at the Ser9 site, resulting in the inhibition of tau phosphorylation [171]. The K252a treatment, a Trk receptor inhibitor, attenuates the effect of BDNF stimulation on tau dephosphorylation [170].

The reduction of the cerebrospinal fluid/plasma IGF-I ratio has been found in AD patients and AD model mice [172, 173], reflecting an impaired uptake of IGF-I from the serum to the CSF. Exercise is known to increase the uptake of IGF-1 in the central nervous system [118]. Elevated IGF-1 not only benefits neuronal functions but also influences the production of Aβ and the formation of neurofibrillary tangles [174]. IGF-1 also affects brain amyloidosis [175, 176]. Crossing APPswe/PS1dE9 Tg mice with serum IGF-I deficient LID mice accelerates brain amyloidosis significantly [175]. Conversely, increases of serum IGF-1 levels decrease the Aβ load in the brain of aged APP/PS2 Tg mice [176]. IGF-1-induced inhibition of amyloidosis could be due to, at least in part, an increase of Aβ clearance. This is because IGF-1 increases the levels of Aβ carrying proteins, such as apolipoprotein J, transthyretin, and albumin, which are all known to facilitate Aβ clearance via blood-brain barrier (BBB) transportation [176, 177]. Antagonization of IGF-1 by TNF-α reduces IGF-I signaling at the BBB, resulting in a decrease of the expression of Aβ-carrying proteins and an increase of Aβ levels in the brain [177]. Furthermore, in vitro cell culture studies (i.e., NT2N cells and rat primary cortical neurons) reveal that IGF-1 induces the phosphorylation of GSK3α (ser21)/β (ser9) and attenuates tau phosphorylation through activating IRS1/PI3K/AKT/mTOR pathway [178, 179]. It has been reported that exercise increases the activity in the IRS/PI3/AKT pathway to dephosphorylate GSK-3α/β [180] and inhibit tau phosphorylation in APP/PS1 [181] and NSE/htau23 Tg mice [182] as well as in the ICV-STZ non-Tg AD model [183]. This supports the assertion that exercise-induced IGF-1 signaling plays an important role in preventing pathologies associated with AD.

Exercise elevates VEGF transcription, mRNA, and protein in the brain [184]. In addition to supporting neurogenesis, VEGF could protect neurons against AD via the following potential mechanisms. Firstly, VEGF increases angiogenesis to help the maintenance of BBB integrity [185, 186], which is essential in preventing the entry of systemic Aβ [187]. Secondly, VEGF regulates the expression of Aβ transporters on the BBB [188]. It has been shown that an implant of VEGF-secreting fibroblast microcapsules into the brain of APP/PS1 mice not only enhances brain vessel density but also increases the level of LRP-1 expression, which is an Aβ efflux transporter on the BBB, accompanied by a reduction of Aβ deposition in the brain [189]. Thirdly, VEGF directly affects APP processing by decreasing β-secretase activity [190, 191]. Applying VEGF to Tg2576 mouse brain slices decreases β-secretase activity and production of both soluble Aβ_{1 - 40} and Aβ_{1 - 42} [190]. Finally, VEGF directly binds to Aβ and eliminates Aβ toxicity. VEGF contains a heparin-binding domain that can be recognized by Aβ [192]; therefore, it is capable of binding to Aβ (at around the 26–35 amino acid region), hence inhibiting Aβ aggregation and Aβ neurotoxicity [192].

Decreases in mature NGF expression as well as increases in Pro-NGF expression have been found in postmortem AD brains [152, 193, 194], suggesting that diminished conversion of pro-NGF to mature NGF and increased degradation in the activity of mature NGF in AD brains [152]. It is known that proNGF preferentially binds to p75NTR and initiates the activation of apoptotic pathways, which may contribute to AD neurodegeneration [195, 196]. Increased mature NGF due to exercise could protect neurons against AD pathologies through acting on the trkA receptor to promote neurite generation, neuronal survival, and synapse formation [197, 198]. It has been reported that exercise-induced increases of mature NGF expression and decreases of Bax expression, the downstream molecule of p75^NTR, are involved in the inhibition of neuronal death during AD development [165]. An in-vivo study of Tg mice expressing a neutralizing antibody directed against NGF showed a progressive development of amyloid deposition and neurofibrillary pathology in the brain [199, 200]. An in-vitro study using PC12 differentiated cells revealed that withdrawal of NGF caused the overproduction of Aβ peptides, increasing tau phosphorylation and neurite degeneration [201, 202]. Similar to BDNF, mature NGF increases the metabolism of APP from amyloidogenic towards non-amyloidogenic processing through binding to the TrkA receptor [203, 204]. Mature NGF is also able to decrease the hyperphosphorylation of tau via increasing the phosphorylation of GSK3 β at the Ser 9 site [204].

Physical activity and AD – glia cells regulations

Accumulated evidence suggests a strong association between risk factors of cerebrovascular disorders, such as hypertension, diabetes, hypercholesterolaemia, hyperhomocysteinaemia, and APOE4, with AD [205]. Astrocytes play an important role in maintaining neurovascular function [205]. The prodromal stage of AD has been linked to dysregulated astrocytes in the neurovascular unit, which may then cause disruptions of neuronal metabolic support, impairment of synaptic functions, onset of neuronal death, and decreases of degradation and clearance of Aβ [206–208]. One of the exercise-induced neuroprotective pathways is mediated by astrocytes. For example, S100B, a calcium-binding protein, is predominantly secreted by astrocytes and acts as a neurotrophic factor to support neuronal survival. In the sporadic AD animal model, five weeks of treadmill exercise could reverse the reduced extracellular levels of S100B [209], suggesting that exercise can alleviate neuronal dysfunction via controlling astrocyte signaling. Furthermore, exercise increases the Aβ clearance abilities of astrocytes in the AD brain. The recently identified glymphatic pathway, which critically relies on AQP4 in astrocytes, contributes to Aβ clearance. Mice lacking the AQP4 in astrocytes exhibit slower paravascular cerebrospinal fluid-interstitial fluid exchange and lower Aβ1-40 clearance rate than those of intact mice [210, 211]. Chronic exercise can increase Aβ clearance through the glymphatic pathway [212]. Two-photon imaging reveals that six weeks of wheel-running increases AQP4 expression in the perivascular region and increases the rate of paravascular cerebrospinal fluid-interstitial fluid exchange in the brain of aged mice; this is accompanied by a decrease of Aβ accumulation in the cortex and hippocampus [212].

In addition to amyloid plaque and neurofibrillary tangle deposition, neuroinflammation is considered a key feature of AD pathology. AD inflammation is characterized by the presence of reactive astrocytes and activated microglia surrounding amyloid plaques. Chronic exercise has been reported to decrease neuroinflammation in AD. In the Tg animal models, wheel-running and treadmill exercise decreased the levels of hippocampal pro-inflammatory cytokines (i.e., IL-1β and TNF-α) of Tg2576 AD mice and NSE/htau23 Tg mice to levels indistinguishable from wild-type mice [213, 214].

Physical activity and AD – Aβ transportation and degradation

LRP-1 and RAGE are major Aβ carrier proteins that regulate Aβ efflux and influx, respectively, in transportation across the BBB [215, 216]. The expression of LRP-1 and RAGE can be detected in both neurons and glial cells [215, 216]. It has been demonstrated that exercise increases LRP-1 and decreases RAGE expression in the hippocampus of Tg2576 [217] and APP/PS1 [71, 181] mice, suggesting enhanced brain-to-blood Aβ transportation after exercise. Also, exercise can increase the activity of Aβ degradation enzymes that prevent the aggregation of Aβ. Tg2576 mice given a 12-week period of exercise significantly increased hippocampal levels of neprilysin, insulin-degrading enzyme, and matrix metallopeptidase 9; all of which are Aβ proteolytic enzymes [217]. Interestingly, exercise-induced changes in the expression levels of Aβ transport proteins and proteolytic degrading enzymes depend on the intensity of exercise training [217].