Project description:Many studies have reported on beneficial aspects of running to improve hippocampus-related spatial memory and promote neuroplastic changes like adult hippocampal neurogenesis (AHN). Such research has also revealed molecular factors associated with molecular signaling by BDNF and IGF-I leading to CREB activation. However, the optimum exercise intensity for genome-wide beneficial effects remains unclear. We thus investigate the whole spectrum of hippocampal molecular change by exercise using DNA microarray-based transcript profiling in two different intensity groups. Lactate threshold (LT), at which lactate starts to accumulate in the blood, defined the intensity: mild- (ME, <LT) or intense-exercise (IE, >LT). Rats were subjected to 6 weeks of training or sedentary (CONT) regimes. After 6 weeks, spatial memory using Morris Water Maze (MWM), AHN, and hippocampal gene expressions were assessed. The functional relationships among the differentially expressed genes were generated using Ingenuity Pathway Analysis and QIAGEN-based pathway analysis. Results revealed that ME, but not IE, improved the performance on probe trial in MWM and increased newborn mature neurons (BrdU+/NeuN+ cells) compared with CONT. Transcript profiling by comparison with CONT postulated that ME regulated protein synthesis through IRS-dependent pathway (e.g. PI3K-Akt signaling cascade), cholesterol trafficking and perisynaptic environment, while IE induced dysfunction of these process and cell death. The comparison of the expression between each intensity also supported these tendencies. Collectively, our findings indicate mild exercise should be beneficial in the development of both enhanced AHN and spatial memory, and several genes related to protein synthesis and lipid-metabolism may be critical those neuroplastic changes. This study is the first step to identify the potential triggers of exercise-induced cognitive gain. Eleven-week-old male Wistar rats (220-270 g; SLC, Saitama, Japan) were housed in polycarbonate steel cages with a 12-h light/dark schedule (lights on at 7:00 a.m.) and given ad libitum access to food and water. A total of 98 rats were used in this study to assess the influence of exercise intensity on physiological states (training effect of skeletal muscle and stress level) (n= 22), MWM (n= 32), AHN (n= 22), and global gene expression profiles of hippocampal by microarray (n= 22). All animal care and experimental procedures were performed in accordance with protocols approved by the University of Tsukuba Animal Experiment Committee, based on the National Institute of Health (NIH) Guidelines for the Care and Use of Laboratory Animals (NIH publication, revised 1996). All efforts were made to minimize animal suffering and to reduce the number of animals used in this study. To adapt the rearing environment and remove any unintended stress effects, animals underwent a week of preliminary rearing to ambient conditions in groups housing conditions (2-3 rats/cage). After the preliminary rearing, the animals were randomized into three groups based on the LT of treadmill running: Sedentary control (CONT, rest on treadmill), Mild Exercise (ME, below LT, 15 m/min) or Intense Exercise (IE, above LT, 40 m/min). Exercise group was habituated to run on a treadmill (KN-73, Natsume Ltd., Tokyo, Japan) for 1 (for ME) or 4 (for IE) weeks. Within a given test period, rats were able to run on the above-mentioned running speeds. After this running habituation, rats were entered into the exercise training session for 6 weeks in total. The running duration was 60 min/day and frequency was 5 times/week. Exercise training was performed between 19:00 and 22:00 (during dark phase). Rat’s body weight and physical condition were monitored until the end of training. If rats could not perform well running on each determined speed and showed poor health, those were eliminated from the study. Based on the criteria, a total of 13 rats were eliminated (bad runner - 4 rats; poor health - 7 rats). Twenty-four or thirty-six hours after the last training, rats were processed to the next step. In the microarray group, the whole brain of each animal was rapidly removed, and hippocampus was separated on ice according to the method of Glowinski and Iversen (1966), with minor modifications. Hippocampi were immediately flash-frozen in liquid nitrogen. The deep-frozen hippocampi were transferred to a pre-chilled (in liquid nitrogen) mortar and pestle, and ground to a very fine powder with liquid nitrogen. The powdered samples were stored in aliquots at -80ºC till used for further analysis. Total RNA was extracted from each sample powder (~50 mg) using the QIAGEN RNeasy Mini Kit (QIAGEN, Maryland, USA). To verify the quality of this RNA, the yield and purity were determined spectrophotometrically (NanoPhotomaterTM, IMPLEN, Munich, Germany) and visually confirmed using formaldehyde gel electrophoresis. We used the sample with a ratio of spectrophotometric absorbance at 260 nm to that at 230 (A260/A230) or 280 nm (A260/A280) above 1.8. An equal amount of RNA (1000 ng) from the five rats, randomly picked up from each exercise group (n = 5), was pooled and used for microarray analysis. In this study, we performed three combinations of comparison analysis of gene expression change. First, we compared the difference between CONT and ME (combination 1) or IE (combination 2) to confirm the exercise-intensity-dependent gene expression change. Subsequently, we made a comparison of ME with IE (combination 3) to elucidate a ME-based difference of IE inducible gene. In all combinations, total RNA (1000 ng) was labeled with either Cy3 or Cy5 dye using an Agilent Low RNA Input Fluorescent Linear Amplification Kit (Agilent Technologies Inc., CA, USA). Fluorescently labeled targets of control as well as treated samples were hybridized to the same microarray slide with 60-mer probes (4 x 44K (41,090 gene probes), rat whole genome, Agilent). A flip labelling (dye-swap or reverse labelling with Cy3 and Cy5 dyes) procedure was followed to nullify the dye bias associated with unequal incorporation of the two Cy dyes into cDNA. Hybridization and wash processes were performed according to the manufacturer’s instructions, and hybridized microarrays were scanned using an Agilent Microarray scanner. For the detection of significantly differentially expressed genes between control and exercise samples each slide image was processed by Agilent Feature Extraction software (version 9.5.3.1).

Project description:Lifestyle induces long lasting effects on the brain and cognition, with some interventions like stress including transgenerational inheritance on the next generations mediated by epigenetic mechanisms. Physical exercise is one potent intervention driving robust improvements of cognition and brain health, also inducing intergenerational transmission to the litter. However, little is known about whether exercise effects may be transgenerationally transmitted. Here we analyzed the adult hippocampal neurogenesis (AHN) and the behavioral phenotype of sedentary adult male mice of the F2 generation of exercised grandfathers (F0, patrilineal design). Both F1 and F2 were sedentary, while F0 performed a moderate exercise training. We found that the F2 mice from exercised F0 acquired and recalled both spatial and non-spatial information better than F2 from sedentary F0. Contextual fear conditioning resulted not affected, together with no differences in the AHN markers. These results demonstrate that the transgenerational transmission of the effects of exercise on specific cognitive tasks persists after two generations, even though some of the cellular changes induced in F1 disappear in F2, and suggest that moderate exercise training has a longer-lasting effect than previously thought, and this aspect is worth taking into account in public health programs.

Project description:Although exercise and dietary interventions on cognitive function have been investigated, synergistic interactions remain unclear. As tested on hippocampus-dependent functions, mild exercise (ME) or astaxanthin (AX), a naturally-occurring antioxidant and cognitive enhancer, each boost the hippocampus-related memory and neurogenesis. Here we show that leptin (LEP) is required for the synergistic enhancement of hippocampal function by a combination of ME and AX. In C57BL/6J mice, ME or AX alone enhanced spatial memory and neurogenesis, but the enhancement was greater with their combination. DNA microarray analysis showed that the up-regulation of the Lep gene by ME alone was further elevated when combined with AX. The combined interventions synergistically increased hippocampal LEP protein, which was positively correlated with memory enhancement. In LEP-deficient mice, the combined interventions did not enhance memory compared to ME alone, leading us to suggest that the brain-derived LEP has an essential role for the synergistic effect on hippocampal functions.

Project description:Neural stem cells residing in the hippocampal neurogenic niche sustain life-long neurogenesis in the adult brain. Adult hippocampal neurogenesis (AHN) is functionally linked to mnemonic and cognitive plasticity in humans and rodents. In Alzheimer’s disease (AD), the process of generating new neurons at the hippocampal neurogenic niche is impeded, yet the mechanisms involved are unknown. Here we identify miR-132, one of the most consistently downregulated microRNAs in AD, as a potent regulator of AHN, exerting cell-autonomous pro-neurogenic effects in the adult neural stem cells and their progeny. Using distinct AD mouse models, cultured human primary and established neural stem cells, and human patient material, we demonstrate that AHN is directly impacted by AD pathology. miR-132 replacement in adult mouse AD hippocampus restores AHN and relevant memory deficits. Our findings corroborate the significance of AHN in AD and reveal the possible therapeutic significance of targeting miR-132 in neurodegeneration.

Project description:BCI-838 is a pro-drug whose active metabolite BCI-632 is an antagonist at the group II metabotropic glutamate receptor (mGluR2/3). Hippocampal dentate gyrus of four-month old mouse model of AD amyloid pathology (APP/PS1) were investigated via transcriptomics analysis following BCI-838 treatment and physical exercise. Findings demonstrate up-regulated brain-derived neurotrophic factor (BDNF), PIK3C2A of the PI3K-MTOR pathway, and metabotropic glutamate receptors, and down-regulated EIF5A of ketamine-modulating mTOR activity. Our study points to BCI-838 as a safe and orally active compound capable of mimicking the beneficial effect of exercise on AHN, learning behavior, and anxiety in a mouse model of AD neuropathology.

Project description:Physical exercise stimulates adult hippocampal neurogenesis in mammals, and is considered a relevant strategy for preventing age-related cognitive decline in aging humans. However, its mechanism is controversial. Here, by investigating microRNAs (miRNAs) and their downstream pathways, we uncover that downregulation of miR-135a-5p mediates exercise-induced proliferation of adult NPCs in adult neurogenesis in the mouse hippocampus, likely by activation of phosphatidylinositol (IP3) signaling. Specifically, while overexpression of miR-135 prevents exercise-induced proliferation in the adult mouse hippocampus in vivo and in NPCs in vitro, its inhibition activates NPCs proliferation in resting and aged mice. Label free proteomics and bioinformatics analysis identifies 11 potential targets of miR-135 in NPCs, several of them involved in phosphatidylinositol signaling. Thus, miR-135a is key in mediating exercise-induced adult neurogenesis and opens intriguing perspectives toward the therapeutic exploitation of miR-135 to delay or prevent pathological brain ageing.Physical exercise stimulates adult hippocampal neurogenesis in mammals, and is considered a relevant strategy for preventing age-related cognitive decline in aging humans. However, its mechanism is controversial. Here, by investigating microRNAs (miRNAs) and their downstream pathways, we uncover that downregulation of miR-135a-5p mediates exercise-induced proliferation of adult NPCs in adult neurogenesis in the mouse hippocampus, likely by activation of phosphatidylinositol (IP3) signaling. Specifically, while overexpression of miR-135 prevents exercise-induced proliferation in the adult mouse hippocampus in vivo and in NPCs in vitro, its inhibition activates NPCs proliferation in resting and aged mice. Label free proteomics and bioinformatics analysis identifies 11 potential targets of miR-135 in NPCs, several of them involved in phosphatidylinositol signaling. Thus, miR-135a is key in mediating exercise-induced adult neurogenesis and opens intriguing perspectives toward the therapeutic exploitation of miR-135 to delay or prevent pathological brain ageing.

Project description:Changes and plasticity in both gene expression and protein signaling in skeletal muscle is considered to be a major cause of metabolic syndrome, while it has been shown that mild exercise training at lactate threshold (LT) intensity is a safe and effective for prevention of metabolic syndrome. To elucidate the molecular mechanisms related to the beneficial effects of LT training for 60 min/day for 5 days/wk for 12 wk, we performed serial analysis of gene expression (SAGE) to examine global mRNA expression in human skeletal muscle. Approximately 57000 SAGE tags were analyzed for before training, as well as 5 days, 6 and 12 wk after the training. The LT training has coordinately induced many genes involved in mitochondrial energy metabolism, fat oxidation, glycolysis and creatine metabolism. Another molecular feature associated with this mild exercise regimen has been an induction of many genes encoding for potent antioxidant enzymes and molecular chaperons. Furthermore, the training modulated the expression levels of 233 novel transcripts. Thus, the current study reveals that LT exercise has favorably altered gene expression in human skeletal muscle to the prevention of metabolic syndrome. Keywords: transcriptome, serial analysis of gene expression, metabolic syndrome, exercise training, lactate threshold

Project description:Exercise has been recognized as a beneficial factor for cognitive health, particularly in relation to the hippocampus, a vital brain region responsible for learning and memory. Previous research has demonstrated that exercise-mediated improvement of learning and memory in humans and rodents correlates with increased adult neurogenesis and processes related to enhanced synaptic plasticity. Nevertheless, the underlying molecular mechanisms are not fully understood. With the aim to further elucidate these mechanisms we provide a comprehensive dataset of the mouse hippocampal transcriptome at the single-cell level after four weeks of voluntary wheel-running. Our analysis provides a number of interesting observations. For example, the results suggest that exercise affects adult neurogenesis by accelerating the maturation of a subpopulation of Prdm16-expressing neurons. Moreover, we uncover the existence of an intricate crosstalk among multiple vital signaling pathways such as NF-κB, Wnt/β-catenin, Notch, retinoic acid (RA) pathways altered upon exercise in a specific cluster of excitatory neurons within the Cornu Ammonis (CA) region of the hippocampus. In conclusion, our study provides an important dataset and sheds further light on the molecular changes induced by exercise in the hippocampus. These findings have implications for developing targeted interventions aimed at optimizing cognitive health and preventing age-related cognitive decline.

Project description:Gene profiling hippocampal mRNA from 1 week sedentary mice vs. 1 week voluntary exercise mice. Keywords: Exercise study.

Project description:Patients with Alzheimer’s disease (AD) exhibit progressive memory loss, depression, and anxiety, accompanied by impaired adult hippocampal neurogenesis (AHN). Whether modulating AHN is sufficient to improve these cognitive and noncognitive symptoms in AD remains elusive. Here we report that chronic stimulation of hypothalamic supramammillary nucleus (SuM) during early AD restores AHN in an otherwise impaired neurogenic niche. Strikingly, activation of SuM-enhanced adult-born neurons (ABNs) is sufficient to restore memory and emotion deficits in 5×FAD mice. Interestingly, activation of SuM-enhanced ABNs in AD mice increases CA3 and CA1 activity. To probe ABN-activity-dependent changes, we performed quantitative phosphoproteomics and found activation of SuM-enhanced ABNs promotes activation of the canonical pathways related to synaptic plasticity and microglia phagocytosis. Functional assays further confirm increased CA1 long-term potentiation and enhanced microglia phagocytosis of plaques upon activation of SuM-enhanced ABNs. Our findings reveal a robust AHN-promoting strategy that is sufficient to restore AD-associated deficits and highlight ABN-activity-dependent mechanisms underlying functional improvement in AD.