Social behavior,hormones and adult neurogenesis

A variety of experiences have been shown to affect the production of neurons in the adult hippocampus. These effects may be mediated by experience-driven hormonal changes, which, in turn, interact with factors such as sex, age and life history to alter brain plasticity. Although the effects of physical experience and stress have been extensively characterized, various types of social experience across the lifespan trigger profound neuroendocrine changes in parallel with changes in adult neurogenesis. This review article focuses on the influence of specific social experiences on adult neurogenesis in the dentate gyrus and the potential role of hormones in these effects.     

Gonadal hormone modulation of neurogenesis in the dentate gyrus of adult male and female rodents

Gonadal hormones modulate neurogenesis in the dentate gyrus differentially in male and female adult rodents. Neurogenesis is comprised of at least two components: cell proliferation (the production of new cells) and cell survival (the number of new neurons that survive to maturity). Previous studies have found sex differences in the level of cell proliferation in the dentate gyrus only when comparing females in a high estrogen state to males. This review focuses on the effects of acute and chronic levels of estrogens or androgens on hippocampal neurogenesis in the adult male and female rodent. Evidence is also reviewed for the co-localization of androgen receptors and estrogen receptors (ER) with markers for cell proliferation or immature new cell survival. Briefly, evidence suggests that acute estradiol initially enhances and subsequently suppresses cell proliferation in the dentate gyrus of adult female rodents but may have limited effects in male rodents. Both the two known ER subtypes, ER and β upregulate hippocampal neurogenesis via cell proliferation. Intriguingly, repeated exposure to estradiol modulates hippocampal neurogenesis and cell death in adult female, but not male, rodents. However short-term estradiol treatment (5 days) in male meadow voles enhances new cell survival in the dentate gyrus but only when administered during the ‘axon extension’ phase. Furthermore, evidence is also reviewed showing a difference in response to acute and chronic estradiol treatment in older female rats compared to younger female rats. Recent findings from our laboratory indicate that testosterone and dihydrotestosterone upregulate hippocampal neurogenesis (via cell survival), but not cell proliferation, in adult male rodents. Effects of endogenous fluctuations in gonadal hormones on adult neurogenesis are observed across the seasons in meadow voles and during pregnancy and lactation in the rat dam. Pregnancy and motherhood differentially regulate adult hippocampal neurogenesis in the adult female rodent, with primiparous rats displaying lower levels of hippocampal cell proliferation and survival after parturition. Few studies have compared males and females but existing research suggests a sex difference in the hormonal regulation of hippocampal neurogenesis in the adult. Clearly more work is needed to elucidate the effects of gonadal hormones on neurogenesis in the dentate gyrus of both male and female rodents across the lifespan, especially if we are to use our knowledge of how adult neurogenesis is regulated to develop strategies to repair neuron loss in neurodegenerative diseases.     

Decline in adult neurogenesis during aging follows a topographic pattern in the mouse hippocampus

In the rodent brain, diverse functions are topographically distributed within the hippocampus. For instance, the dorsal (septal) hippocampus is involved in spatial memory, whereas the ventral (temporal) hippocampus is related to emotion and anxiety. Accumulating evidence shows that age-dependent decline in hippocampal neurogenesis is associated with impairments of these functions. However, little is known about whether the decline in dentate granule cell production during aging follows a topographic pattern. Here we quantitatively estimated specific populations of adult-born cells in young adult and middle-aged mice by using endogenous markers and determined whether age-dependent reductions in adult neurogenesis exhibited topographic differences. The numerical densities (NDs) of putative primary progenitors, intermediate neuronal progenitors, and neuronal lineages were higher in the dorsal dentate gyrus (DG) than in the ventral DG both in young adult and in middle-aged mice, but the ratios of the NDs in the dorsal DG to the NDs in the ventral DG noticeably increased with age. The age-related reductions in the numbers of these populations were larger in the ventral DG than in the dorsal DG. By contrast, the NDs of glial lineages were higher in the ventral DG than in the dorsal DG during life, and the numbers of glial lineages showed no significant age-related changes. Our findings suggest that neurogenesis, but not gliogenesis, wanes faster in the ventral hippocampus than in the dorsal hippocampus during aging. Such age-related topographic changes in hippocampal neurogenesis might be implicated in memory and affective impairments in older people.     

Functions for adult neurogenesis in memory: an introduction to the neurocomputational approach and to its contribution

Until recently, it was believed that the introduction of new neurons in neuronal networks was incompatible with memory function. Since the rediscovery of adult hippocampal neurogenesis, behavioral data demonstrate that adult neurogenesis is required for memory processing. We examine neurocomputational studies to identify which basic mechanisms involved in memory might be mediated by adult neurogenesis. Mainly, adult neurogenesis might be involved in the reduction of catastrophic interference and in a time-related pattern separation function. Artificial neuronal networks suggest that the selective recruitment of new-born or old neurons is not stochastic, but depends on environmental requirements. This leads us to propose the novel concept of “soft-supervision”. Soft-supervision would be a biologically plausible process, by which the environment is able to influence activation and learning rules of neurons differentially.     

Glucocorticoid signaling and exercise-induced downregulation of the mineralocorticoid receptor in the induction of adult mouse dentate neurogenesis by treadmill running

Physical exercise is known to promote adult neurogenesis, although the underlying mechanisms remain unclear. Glucocorticoid (corticosterone in rodents) is a factor that is known to affect neurogenesis. As physical exercise modulates corticosterone secretion, we hypothesized that corticosterone signaling is involved in exercise-induced adult neurogenesis. We chose treadmill running (TR) to accurately define the intensity and duration of exercise. Our results showed that 5 weeks of TR increased the doublecortin (DCX)-positive neuronal progenitor cells (NPCs) in adult hippocampus and transiently increased the serum corticosterone level at the end of the TR protocol. This protocol reduced the levels of hippocampal mineralocorticoid receptor (MR); however, glucocorticoid receptor levels were unaltered. We then investigated whether reducing corticosterone levels by bilateral adrenalectomy (ADX) attenuated the TR-enhanced adult neurogenesis. Our results showed that ADX not only blocked the TR-induced downregulation of MR, but also reduced the number of TR-enhanced NPCs. In order to examine the role of MR downregulation in TR-induced adult neurogenesis, animals were treated repeatedly with a selective MR antagonist, spironolactone, for 3 weeks. The results revealed that spironolactone increased the number of spontaneously occurring and TR-induced NPC in the dentate area. Further analysis revealed that spironolactone treatment did not alter precursor cell proliferation, but increased the number of DCX-positive NPCs, suggesting that blockage of MR signaling either facilitates the differentiation of progenitor cells towards neurons and/or enhances the survival of NPCs. Taken together, the data indicated that induction of NPCs in the dentate area of adult hippocampus by TR is partly due to the downregulation of glucocorticoid/MR signaling, which subsequently enhances differentiation along a neuronal lineage and/or NPC survival.     

Effects of maternal behavior induction and pup exposure on neurogenesis in adult, virgin female rats

The states of pregnancy and lactation bring about a range of physiological and behavioral changes in the adult mammal that prepare the mother to care for her young. Cell proliferation increases in the subventricular zone (SVZ) of the female rodent brain during both pregnancy and lactation when compared to that in cycling, diestrous females. In the present study, the effects of maternal behavior induction and pup exposure on neurogenesis in nulliparous rats were examined in order to determine whether maternal behavior itself, independent of pregnancy and lactation, might affect neurogenesis. Adult, nulliparous, Sprague-Dawley, female rats were exposed daily to foster young in order to induce maternal behavior. Following the induction of maternal behavior each maternal subject plus females that were exposed to pups for a comparable number of test days, but did not display maternal behavior, and subjects that had received no pup exposure were injected with bromodeoxyuridine (BrdU, 90 mg/kg, i.v.). Brain sections were double-labeled for BrdU and the neural marker, NeuN, to examine the proliferating cell population. Increases in the number of double-labeled cells were found in the maternal virgin brain when compared with the number of double-labeled cells present in non-maternal, pup-exposed nulliparous rats and in females not exposed to young. No changes were evident in the dentate gyrus of the hippocampus as a function of maternal behavior. These data indicate that in nulliparous female rats maternal behavior itself is associated with the stimulation of neurogenesis in the SVZ.     

Enhanced neurogenesis during trimethyltin-induced neurodegeneration in the hippocampus of the adult rat

The occurrence of neurogenesis in the hippocampus of the adult rat during trimethyltin (TMT)-induced neurodegeneration was investigated using bromodeoxyuridine (BrdU). Fifteen days after TMT intoxication, BrdU-labeled cells were significantly more numerous in the hippocampus of treated animals, gradually decreasing towards the control value 21 days after intoxication in the dentate gyrus (DG), while in the CA3/hilus region BrdU-labeled cells were still more numerous in TMT-treated rats. In order to investigate the fate of newly-generated cells double labeling experiments using neuronal or glial markers were performed. Colocalization of the neuronal marker NeuN was detected in many BrdU-positive cells in the DG, while in the CA3/hilus region no colocalization of NeuN and BrdU could be observed. No colocalization of BrdU and the astroglial marker GFAP or the microglial marker OX-42 was detected either in the DG and or in the CA3/hilus region. The results indicate an enhancement of endogenous neurogenesis in the hippocampus during TMT-induced neurodegeneration, with the development of a subpopulation of regenerated cells into neurons in the DG, while in the CA3/hilus region the population of newly-generated cells should be regarded as undifferentiated.     

Neurogenesis in the adult hippocampus: history,regulation, and prospective roles

Background: The hippocampus is one of the sites in the mammalian brain that is capable of continuously generating controversy. Adult neurogenesis is a remarkable process, and yet an intensely debatable topic in contemporary neuroscience due to its distinctiveness and conceivable impact on neural activity. The belief that neurogenesis continues through adulthood has provoked remarkable efforts to describe how newborn neurons differentiate and incorporate into the adult brain. It has also encouraged studies that investigate the consequences of inadequate neurogenesis in neuropsychiatric and neurodegenerative diseases and explore the potential role of neural progenitor cells in brain repair. The adult nervous system is not static; it is subjected to morphological and physiological alterations at various levels. This plastic mechanism guarantees that the behavioral regulation of the adult nervous system is adaptable in response to varying environmental stimuli. Three regions of the adult brain, the olfactory bulb, the hypothalamus, and the hippocampal dentate gyrus, contain new-born neurons that exhibit an essential role in the natural functional circuitry of the adult brain. Purpose/Aim: This article explores current advancements in adult hippocampal neurogenesis by presenting its history and evolution and studying its association with neural plasticity. The article also discusses the prospective roles of adult hippocampal neurogenesis and describes the intracellular, extracellular, pathological, and environmental factors involved in its regulation. Abbreviations AHN Adult hippocampal neurogenesis

AKT Protein kinase B

BMP Bone Morphogenic Protein

BrdU Bromodeoxyuridine

CNS Central nervous system

DG Dentate gyrus

DISC1 Disrupted-in-schizophrenia 1

FGF-2 Fibroblast Growth Factor 2

GABA Gamma-aminobutyric acid

Mbd1 Methyl-CpG-binding domain protein 1

Mecp2 Methyl-CpG-binding protein 2

mTOR Mammalian target of rapamycin

NSCs Neural stem cells

OB Olfactory bulb; P21: cyclin-dependent kinase inhibitor 1

RBPj Recombination Signal Binding protein for Immunoglobulin Kappa J Region

RMS Rostral migratory Stream

SGZ Subgranular zone

Shh Sonic hedgehog

SOX2 SRY (sex determining region Y)-box 2

SVZ Subventricular zone

Wnt3 Wingless-type mouse mammary tumor virus

     

Circadian and ultradian glucocorticoid rhythmicity: Implications for the effects of glucocorticoids on neural stem cells and adult hippocampal neurogenesis

Psychosocial stress, and within the neuroendocrine reaction to stress specifically the glucocorticoid hormones, are well-characterized inhibitors of neural stem/progenitor cell proliferation in the adult hippocampus, resulting in a marked reduction in the production of new neurons in this brain area relevant for learning and memory. However, the mechanisms by which stress, and particularly glucocorticoids, inhibit neural stem/progenitor cell proliferation remain unclear and under debate.Here we review the literature on the topic and discuss the evidence for direct and indirect effects of glucocorticoids on neural stem/progenitor cell proliferation and adult neurogenesis. Further, we discuss the hypothesis that glucocorticoid rhythmicity and oscillations originating from the activity of the hypothalamus-pituitary-adrenal axis, may be crucial for the regulation of neural stem/progenitor cells in the hippocampus, as well as the implications of this hypothesis for pathophysiological conditions in which glucocorticoid oscillations are affected.     

A reward increases running-wheel performance without changing cell proliferation, neuronal differentiation or cell death in the dentate gyrus of C57BL/6 mice

Exercise is one of the best-known stimulators of adult hippocampal neurogenesis, but it is not known if voluntary changes in the intensity of exercise are accompanied by changes in neurogenesis. In this study we investigated whether a reward influences the performance in a running wheel and the rate of cell proliferation, neuronal differentiation and cell death in C57BL/6 mice. Mice had free access to a running wheel during the first week of the experiment. In the second week, animals were rewarded for their performance and compared to normal voluntary running and control mice. A reward significantly increased the performance by 78% when compared to the non-rewarded performance of the first week. The performance of the non-rewarded runners remained relatively constant. Fourteen days of exercise significantly increased cell proliferation by 27% and the number of doublecortin immunoreactive cells by 46%. A reward and the associated increase of performance did not modulate proliferation, cell death or the number of cells entering the neuronal lineage. We suggest that, in C57BL/6 mice, either exercise increases adult hippocampal neurogenesis to a ceiling value, which is reached by a performance at or below the level achieved by voluntary wheel running, or that a possible positive effect of increased running-wheel activity is balanced by stress resulting from rewarded running, which is no longer performed on a strictly voluntary basis.     

脑卒中后抑郁大鼠海马原位增殖的新生细胞存活和分化状态

目的 观察脑卒中后抑郁(post-stroke depression,PSD)大鼠海马原位增殖新生细胞的存活和分化.方法 采用左侧大脑中动脉阻塞(MCAO)联合慢性不可预见温和应激刺激(chronicmild stress,CMS)及孤养法建立PSD模型,将雄性SD大鼠分为假手术、脑卒中、CMS和PSD组.每组均为18只.采取免疫组织化学、荧光双标染色及共聚焦成像动态检测,比较各研究组大鼠左侧海马齿状回溴脱氧尿苷嘧啶(BrdU)及其与神经元特异性核蛋白(NeuN)或胶质纤维酸性蛋白(GFAP)共表达.结果 与脑卒中组(232.2±8.6、123.7±2.6、136.2±2.6)相比,PSD组大鼠左侧(伤侧)海马齿状回BrdU+细胞数在脑梗死后第21(156.2±2.5)、30(70.2±2.0)和45天(81.2±1.1)均明显减少(t=28.83、52.2、62.08,均P<0.01),但仍高于假手术组.与脑卒中组(79.3%±2.8%、87.7%±4.6%)相比,PSD组大鼠左侧(伤侧)海马齿状回BrdU+/NeuN+细胞比例在脑梗死后第30(69.0%±3.4%)和45天(78.3%±2.4%)均明显减少(t=5.871、4.403,均P<0.01).BrdU+/GFAP+细胞比例在脑梗死后30和45 d均明显增加(t=4.226、8.945,P<0.01).结论 PSD大鼠脑卒中后海马齿状回原位增殖的新生细胞存活降低,分化为神经元的比例下降,胶质细胞比例增加.     

Activities of the pituitary–adrenal and gonadal axes during the estrous cycle in adult female rats prenatally exposed to morphine

The present investigation concerns 80–90-day-old female rats born from morphine-exposed mothers (2×10 mg/kg per day from day 11–18 of gestation) or saline-treated ones (controls). The former showed reduced size and activity of the adrenals at birth. At adult stage, they present: (1) higher increase of plasma adrenocorticotrophic hormone level on proestrus; (2) significant rise of plasma corticosterone level on diestrus morning and estrus evening; (3) adrenal atrophy which was significant only on diestrus and estrus morning; (4) more corticosterone binding sites of type I (mineralocorticoid receptors) on proestrus morning in the hippocampus; (5) more corticosterone binding sites of type II (glucocorticoid receptors) in the hippocampus on proestrus morning and in the hypothalamus on estrus morning. In both experimental groups, B_max for hypothalamic mineralocorticoid receptors were drastically higher on estrus morning than on the other stages of the estrous cycle. The activity of the pituitary–gonadal axis is poorly affected by prenatal morphine-exposition. In both experimental groups drastic and comparable surges of both plasma progesterone and luteinizing hormone were observed during proestrus. Nevertheless morphine-exposed females showed higher levels of plasma estradiol on diestrus morning but lower levels on metestrus morning. In conclusion, prenatal exposition to morphine has long-term effects mainly on pituitary–adrenal axis as well as on binding sites for corticosterone in the hypothalamus and the hippocampus which are dependent on the estrous cycle stages in adult females.     

Seasonal regulation of structural plasticity and neurogenesis in the adult mammalian brain: Focus on the sheep hypothalamus

To cope with variations in the environment, most mammalian species exhibit seasonal cycles in physiology and behaviour. Seasonal plasticity during the lifetime contributes to seasonal physiology. Over the years, our ideas regarding adult brain plasticity and, more specifically, hypothalamic plasticity have greatly evolved. Along with the two main neurogenic regions, namely the hippocampal subgranular and lateral ventricle subventricular zones, the hypothalamus, which is the central homeostatic regulator of numerous physiological functions that comprise sexual behaviours, feeding and metabolism, also hosts neurogenic niches. Both endogenous and exogenous factors, including the photoperiod, modulate the hypothalamic neurogenic capacities. The present review describes the effects of season on adult morphological plasticity and neurogenesis in seasonal species, for which the photoperiod is a master environmental cue for the successful programming of seasonal functions. In addition, the potential functional significance of adult neurogenesis in the mediation of the seasonal control of reproduction and feeding is discussed.     

The inhibitory effect of sleep deprivation on cell proliferation in the hippocampus of adult mice is eliminated by corticosterone clamp combined with interleukin-1 receptor 1 knockout

Deprivation or fragmentation of sleep for longer than 2 days significantly inhibits cell proliferation and neurogenesis in the hippocampus of adult rats and mice. Signaling pathways that mediate these effects have yet to be clarified. Although deprivation procedures can stimulate adrenal corticosterone (CORT) release, suppression of cell proliferation by sleep deprivation does not require elevated CORT. We examined a role for interleukin-1β (IL-1β), a pro-inflammatory cytokine that is increased by sleep loss and that mediates effects of stress on hippocampal neurogenesis. Wild type (WT) and IL-1 receptor 1 knockout (IL1RI-KO) mice were subjected to rapid-eye-movement sleep deprivation (RSD) for 72-h using the multiple platform-over-water method. Mice were administered BrdU (100 mg/kg) i.p. at hour 70 of RSD and were sacrificed 2-h later. New cells were identified by immunoreactivity (ir) for BrdU and Ki67 in the granular cell layer/subgranular zone (GCL/SGZ) and the hilus. In Experiment 1, WT and IL1RI-KO mice, by contrast with respective control groups, exhibited significantly fewer BrdU-ir and Ki67-ir cells. In Experiment 2, WT and IL1RI-KO mice were adrenalectomized (ADX) and maintained on constant low-dose CORT by osmotic minipumps. RSD reduced cell proliferation by 32% (p < 0.01) in ADX-WT animals but did not significantly reduce proliferation in ADX IL1RI-KO animals (p > 0.1). These results imply that RSD suppresses cell proliferation by the presence of wake-dependent factors (either elevated CORT or IL-1β signaling are sufficient), rather than the absence of a REM sleep-dependent process. The generality of these findings to other sleep deprivation methods and durations remains to be established.     

戊四氮点燃过程中大鼠海马 BMP4表达与神经增殖关系

目的探讨戊四氮(PTZ)点燃过程中大鼠海马骨形成蛋白4(bone morphogenetic protein-4,BMP4)的表达变化与神经增殖的关系。方法将成年大鼠分为对照组与模型组,模型组大鼠又根据在点燃中的不同时相点分为9组。用免疫组织化学与原位杂交的方法检测海马齿状回BMP4mRNA与BrdU阳性细胞数的变化。结果正常成年大鼠BMP4阳性细胞主要分布于齿状回的门区、颗粒下层、CA3、CA1区。BrdU阳性细胞主要分布在齿状回颗粒下层。BMP4阳性细胞与BrdU阳性细胞在点燃过程中均明显增加,呈明显正相关,点燃后2月降至基线水平。结论BMP4可能通过影响成年大鼠海马神经发生在PTZ点燃过程中起重要作用。     

Characterization of the neurogenesis quiescent zone in the rodent brain: Effects of age and exercise

Although it is accepted that new neurons continue to be generated in the hippocampal dentate gyrus (DG) throughout adulthood, it has recently become apparent that this process is not homogeneous, and that a small region of the DG lacks neurogenesis. Here, we show that the relative area of this neurogenesis quiescent zone (NQZ) did not vary after the peak in hippocampal postnatal neurogenesis and until animals reached adulthood, although the ratio between its actual volume and the total volume of the DG doubled during this time. However, we were able to identify a few mitotic cells that reside within this subregion in early adolescent rats. Furthermore, these cells can be activated, and 1 week of voluntary exercise was enough to significantly increase the number of mitotic cells within the NQZ of adolescent rats. There was, however, no corresponding increase in the number of new neurons in this subregion of the DG, suggesting that some factor necessary to allow these cells to develop into a mature phenotype is missing. Moreover, the same intervention was ineffective in increasing either proliferation or neurogenesis in older adult rats. Surprisingly, we found no evidence for the existence of an NQZ in the mouse DG, suggesting that the neurogenic process in these two rodent species is differently regulated. Understanding the molecular mechanisms underlying the existence of the NQZ in the rat DG might shed light on the processes that regulate adult neurogenesis and its modulation by factors such as aging and exercise.     

慢性应激对大鼠海马CA3区锥体细胞顶树突及血清皮质酮浓度的影响

目的探讨慢性应激对大鼠海马CA3区锥体细胞结构和血清皮质酮浓度的影响。方法将20只雄性Sprague-Dawley大鼠按体质量随机分为应激组和对照组,每组10只。采用高尔基染色法及酶联免疫分析方法,观察慢性强迫游泳应激对大鼠海马CA3区锥体细胞顶树突和血清皮质酮浓度的影响。结果应激组大鼠海马CA3区锥体细胞顶树突的总长度[(112±10)μm]短于对照组[(168±34)μm],差异有统计学意义(P<0.01);一级树突直径[(9.0±1.1)μm]大于对照组[(5.7±0.9)μm],差异有统计学意义(P<0.01);血清皮质酮浓度[(13±14)μg/L]低于对照组[(30±16)μg/L],差异有统计学意义(P<0.05)。结论慢性强迫游泳可引起大鼠海马CA3区锥体细胞顶树突及血清皮质酮浓度的改变。     

Repeated restraint stress and corticosterone injections during late pregnancy alter GAP-43 expression in the hippocampus and prefrontal cortex of rat pups

In the offspring of prenatal stress animals, overactivity and impaired negative feedback regulation of the hypothalamic–pituitary–adrenal axis are consistent finding. However, little was known about how prenatal stress can permanently alter developmental trajectories of pup's brain. Growth-associated protein-43 (GAP-43) is a presynaptic membrane phosphoprotein whose expression increases during developmental events such as axonal outgrowth or remodeling and synaptogenesis. Phosphorylation of GAP-43 by protein kinase C was correlated with enhanced axonal growth and transmitter release. In adult animals, increase of GAP-43 correlated with monoaminergic deficit in neuropsychiatric disorders. The present study examines the effects of repeated maternal restraint stress on the level of GAP-43 in the brain of rat pups. The results showed that prenatal stress significantly increased GAP-43 level in the PFC of rat pup during PND 7–14 as compared to control but not significant difference when observed at PND 21. Increased GAP-43 expression was also observed in the pup's hippocampus during the same postnatal periods. However, when observed at PND 60, pups born from stressed mother showed a significant lower (p < 0.001) GAP-43 expression as compare with control group. These changes indicate the direct effect of corticosteroid hormone, since repeated maternal injection with corticosterone (CORT, 40 mg/kg) during GD 14–21 also gave the same results. PND 7–14 is the peak period of synaptogenesis in these brain areas and abnormal axon sprouting and reorganization may lead to a defect in synaptic pruning at later stage of life. The results suggested that maternal stress is harmful to the developing brain and upregulation of GAP-43 indicated a protective mechanism against the toxicity of maternal stress hormone. Prenatal stress alter the normal developmental trajectories in the pup's brain may underlies the mechanism link between early life stress and neuropsychopathology in later life.