Koshiro Inoue

Reduction in paracrine Wnt3 factors during aging causes impaired adult neurogenesis

The mammalian brain contains neural stem cells (NSCs) that enable continued neurogenesis throughout adulthood. However, NSC function and/or numbers decline with increasing age. Adult hippocampal neurogenesis is unique in that astrocytes secreting Wnt3 promote NSC differentiation in a paracrine manner. Here, we show that both the levels of Wnt3 protein and the number of Wnt3‐secreting astrocytes influence the impairment of adult neurogenesis during aging. The age‐associated reduction in Wnt3 levels affects the regulation of target genes, such as NeuroD1 and retrotransposon L1, as well as the expression of Dcx, which is located adjacent to the L1 loci. Interestingly, the decline in the extrinsic Wnt3 levels and in the intracellular expression of the target genes with aging was reversible. Exercise was found to significantly increase de novo expression of Wnt3 and thereby rescue impaired neurogenesis in aged animals. Furthermore, the chromatin state of NeuroD1, L1, and the L1 loci near Dcx changed relative to Wnt3 levels in an age‐ or stimulus‐associated manner. These results suggest that the regulation of paracrine factors plays a critical role in hippocampal aging and neurogenesis.—Okamoto, M., Inoue, K., Iwamura, H., Terashima, K., Soya, H., Asashima, M., Kuwabara, T. Reduction in paracrine Wnt3 factors during aging causes impaired adult neurogenesis. FASEB J. 25, 3570–3582 (2011). www.fasebj.org

Mild exercise increases dihydrotestosterone in hippocampus providing evidence for androgenic mediation of neurogenesis

Mild exercise activates hippocampal neurons through the glutamatergic pathway and also promotes adult hippocampal neurogenesis (AHN). We hypothesized that such exercise could enhance local androgen synthesis and cause AHN because hippocampal steroid synthesis is facilitated by activated neurons via N-methyl-D-aspartate receptors. Here we addressed this question using a mild-intense treadmill running model that has been shown to be a potent AHN stimulator. A mass-spectrometric analysis demonstrated that hippocampal dihydrotestosterone increased significantly, whereas testosterone levels did not increase significantly after 2 wk of treadmill running in both orchidectomized (ORX) and sham castrated (Sham) male rats. Furthermore, analysis of mRNA expression for the two isoforms of 5α-reductases (srd5a1, srd5a2) and for androgen receptor (AR) revealed that both increased in the hippocampus after exercise, even in ORX rats. All rats were injected twice with 5′-bromo-2′deoxyuridine (50 mg/kg body weight, i.p.) on the day before training. Mild exercise significantly increased AHN in both ORX and Sham rats. Moreover, the increase of doublecortin or 5′-bromo-2′deoxyuridine/NeuN-positive cells in ORX rats was blocked by s.c. flutamide, an AR antagonist. It was also found that application of an estrogen receptor antagonist, tamoxifen, did not suppress exercise-induced AHN. These results support the hypothesis that, in male animals, mild exercise enhances hippocampal synthesis of dihydrotestosterone and increases AHN via androgenenic mediation.

Brain glycogen supercompensation following exhaustive exercise

Non‐technical summary  Exercise training elicits an increase in the basal level of muscular glycogen. This happens when glycogen recovers to above its basal level (supercompensation) after it decreases with acute exercise. Although untested, it is hypothesized that, similar to that of skeletal muscle, brain glycogen supercompensation occurs after acute exhaustive exercise. We provide evidence that exhaustive exercise induces glycogen supercompensation not only in skeletal muscles, but also in the brain. Furthermore, we observed exercise training‐induced increases in basal glycogen levels in the cortex and hippocampus, which are involved in motor control and cognitive function. This suggests that, like skeletal muscles, the brain adapts metabolically, probably to meet the increased energy demands of exercise training.

Cessation of voluntary wheel running increases anxiety-like behavior and impairs adult hippocampal neurogenesis in mice

While increasing evidence demonstrates that physical exercise promotes brain health, little is known on how the reduction of physical activity affects brain function. We investigated whether the cessation of wheel running alters anxiety-like and depression-like behaviors and its impact on adult hippocampal neurogenesis in mice. Male C57BL/6 mice (4 weeks old) were assigned to one of the following groups, and housed until 21 weeks old; (1) no exercise control (noEx), housed in a standard cage; (2) exercise (Ex), housed in a running wheel cage; and (3) exercise-no exercise (Ex-noEx), housed in a running wheel cage for 8 weeks and subsequently in a standard cage. Behavioral evaluations suggested that Ex-noEx mice were more anxious compared to noEx control mice, but no differences were found in depression-like behavior. The number of BrdU-labeled surviving cells in the dentate gyrus was significantly higher in Ex but not in Ex-noEx compared with noEx, indicating that the facilitative effects of exercise on cell survival are reversible. Surprisingly, the ratio of differentiation of BrdU-positive cells to doublecortin-positive immature neurons was significantly lower in Ex-noEx compared to the other groups, suggesting that the cessation of wheel running impairs an important component of hippocampal neurogenesis in mice. These results indicate that hippocampal adaptation to physical inactivity is not simply a return to the conditions present in sedentary mice. As the impaired neurogenesis is predicted to increase a vulnerability to stress-induced mood disorders, the reduction of physical activity may contribute to a greater risk of these disorders.

Voluntary resistance running with short distance enhances spatial memory related to hippocampal BDNF signaling

Although voluntary running has beneficial effects on hippocampal cognitive functions if done abundantly, it is still uncertain whether resistance running would be the same. For this purpose, voluntary resistance wheel running (RWR) with a load is a suitable model, since it allows increased work levels and resultant muscular adaptation in fast-twitch muscle. Here, we examined whether RWR would have potential effects on hippocampal cognitive functions with enhanced hippocampal brain-derived neurotrophic factor (BDNF), as does wheel running without a load (WR). Ten-week-old male Wistar rats were assigned randomly to sedentary (Sed), WR, and RWR (to a maximum load of 30% of body weight) groups for 4 wk. We found that in RWR, work levels increased with load, but running distance decreased by about half, which elicited muscular adaptation for fast-twitch plantaris muscle without causing any negative stress effects. Both RWR and WR led to improved spatial learning and memory as well as gene expressions of hippocampal BDNF signaling-related molecules. RWR increased hippocampal BDNF, tyrosine-related kinase B (TrkB), and cAMP response element-binding (CREB) protein levels, whereas WR increased only BDNF. With both exercise groups, there were correlations between spatial memory and BDNF protein (r = 0.41), p-CREB protein (r = 0.44), and work levels (r = 0.77). These results suggest that RWR plays a beneficial role in hippocampus-related cognitive functions associated with hippocampal BDNF signaling, even with short distances, and that work levels rather than running distance are more determinant of exercise-induced beneficial effects in wheel running with and without a load.

Long-term Mild Exercise Training Enhances Hippocampus-dependent Memory in Rats

Although exercise training improves hippocampus-related cognition, the optimum exercise intensity is still disputed. Based on the lactate threshold (LT, approximately 20 m/min on treadmill) of rats, we have shown that 2 weeks of training with stress-free mild exercise (ME, LT), comprising exercise stress, promotes adult hippocampal neurogenesis (Okamoto et al., PNAS, 2012), a potential substrate for memory improvement. These results led us to postulate that long-term ME, but not IE, training leads to improved hippocampal function as assessed with a Morris water maze (MWM) task. To test this hypothesis, we investigated the changes in physiological stress levels and MWM task performance in rats assigned to 6 weeks of sedentary control (CONT), ME-training or IE-training conditions. Results showed that, compared to the other conditions, only IE causes general adaptive syndrome (GAS), including adrenal hypertrophy, thymic atrophy and hypercorticosteronemia. In the MWM, ME led to enhanced memory, but not learning, compared with CONT, while IE produced no change in either capacity, probably due to GAS. These findings support the hypothesis that 6 weeks of continuous ME training leads to enhanced hippocampus-related memory, which may have implications for both healthy adults and subjects with low physical capacity.

DNA microarray‐based analysis of voluntary resistance wheel running reveals novel transcriptome leading robust hippocampal plasticity

In two separate experiments, voluntary resistance wheel running with 30% of body weight (RWR), rather than wheel running (WR), led to greater enhancements, including adult hippocampal neurogenesis and cognitive functions, in conjunction with hippocampal brain‐derived neurotrophic factor (BDNF) signaling (Lee et al., J Appl Physiol, 2012; Neurosci Lett., 2013). Here we aimed to unravel novel molecular factors and gain insight into underlying molecular mechanisms for RWR‐enhanced hippocampal functions; a high‐throughput whole‐genome DNA microarray approach was applied to rats performing voluntary running for 4 weeks. RWR rats showed a significant decrease in average running distances although average work levels increased immensely, by about 11‐fold compared to WR, resulting in muscular adaptation for the fast‐twitch plantaris muscle. Global transcriptome profiling analysis identified 128 (sedentary × WR) and 169 (sedentary × RWR) up‐regulated (>1.5‐fold change), and 97 (sedentary × WR) and 468 (sedentary × RWR) down‐regulated (<0.75‐fold change) genes. Functional categorization using both pathway‐ or specific‐disease‐state‐focused gene classifications and Ingenuity Pathway Analysis (IPA) revealed expression pattern changes in the major categories of disease and disorders, molecular functions, and physiological system development and function. Genes specifically regulated with RWR include the newly identified factors of NFATc1, AVPR1A, and FGFR4, as well as previously known factors, BDNF and CREB mRNA. Interestingly, RWR down‐regulated multiple inflammatory cytokines (IL1B, IL2RA, and TNF) and chemokines (CXCL1, CXCL10, CCL2, and CCR4) with the SYCP3, PRL genes, which are potentially involved in regulating hippocampal neuroplastic changes. These results provide understanding of the voluntary‐RWR‐related hippocampal transcriptome, which will open a window to the underlying mechanisms of the positive effects of exercise, with therapeutic value for enhancing hippocampal functions.