During immature stages, adult-born neurons pass through critical periods for survival and plasticity. It is generally assumed that by 2 months of age adult-born neurons are mature and equivalent to the broader neuronal population, raising questions of how they might contribute to hippocampal function in old age when neurogenesis has declined. However, few have examined adult-born neurons beyond the critical period or directly compared them to neurons born in infancy. Here, we used a retrovirus to visualize functionally relevant morphological features of 2-to 24-week-old adult-born neurons in male rats. From 2 to 7 weeks, neurons grew and attained a relatively mature phenotype. However, several features of 7-week-old neurons suggested a later wave of growth: these neurons had larger nuclei, thicker dendrites, and more dendritic filopodia than all other groups. Indeed, between 7 and 24 weeks, adult-born neurons gained additional dendritic branches, formed a second primary dendrite, acquired more mushroom spines, and had enlarged mossy fiber presynaptic terminals. Compared with neonatal-born neurons, old adult-born neurons had greater spine density, larger presynaptic terminals, and more putative efferent filopodial contacts onto inhibitory neurons. By integrating rates of cell birth and growth across the life span, we estimate that adult neurogenesis ultimately produces half of the cells and the majority of spines in the dentate gyrus. Critically, protracted development contributes to the plasticity of the hippocampus through to the end of life, even after cell production declines. Persistent differences from neonatal-born neurons may additionally endow adult-born neurons with unique functions even after they have matured.
During immature stages, adult-born neurons pass through critical periods for survival and plasticity. It is generally assumed that by 2 months of age adult-born neurons are mature and equivalent to the broader neuronal population, raising questions of how they might contribute to hippocampal function in old age when neurogenesis has declined. However, few have examined adult-born neurons beyond the critical period, or directly compared them to neurons born in infancy. Here, we used a retrovirus to visualize functionally-relevant morphological features of 2- to 24-week-old adult-born neurons in male rats. From 2-7 weeks neurons grew and attained a relatively mature phenotype. However, several features of 7-week-old neurons suggested a later wave of growth: these neurons had larger nuclei, thicker dendrites and more dendritic filopodia than all other groups. Indeed, between 7-24 weeks, adult-born neurons gained additional dendritic branches, grew a 2nd primary dendrite, acquired more mushroom spines and had enlarged mossy fiber presynaptic terminals. Compared to neonatally-born neurons, old adult-born neurons had greater spine density, larger presynaptic terminals, and more putative efferent filopodial contacts onto inhibitory neurons. By integrating rates of cell birth and growth across the lifespan, we estimate that adult neurogenesis ultimately produces half of the cells and the majority of spines in the dentate gyrus. Critically, protracted development contributes to the plasticity of the hippocampus through to the end of life, even after cell production declines. Persistent differences from neonatally-born neurons may additionally endow adult-born neurons with unique functions even after they have matured.SIGNIFICANCE STATEMENTNeurogenesis occurs in the hippocampus throughout adult life and contributes to memory and emotion. It is generally assumed that new neurons have the greatest impact on behavior when they are immature and plastic. However, since neurogenesis declines dramatically with age, it is unclear how they might contribute to behavior later in life when cell proliferation has slowed. Here we find that newborn neurons mature over many months in rats, and end up with distinct morphological features compared to neurons born in infancy. Using a mathematical model, we estimate that a large fraction of neurons is added in adulthood. Moreover, their extended growth produces a reserve of plasticity that persists even after neurogenesis has declined to low rates.
Rewards are often unreliable and optimal choice requires behavioral flexibility and learning about the probabilistic nature of uncertain rewards. Probabilistic learning occurs over multiple trials, often without conscious knowledge, and is traditionally associated with striatal function. While the hippocampus is classically recognized for its role in memory for individual experiences, recent work indicates that it is also involved in probabilistic forms of learning but little is known about the features that support such learning. We hypothesized that adult neurogenesis may be involved, because adult-born neurons contribute to both learning and reward-related behaviors. To test this, we used an appetitive probabilistic reversal learning task where a correct lever is rewarded with 80% probability and an incorrect lever is rewarded with 20% probability. Behavioral flexibility was assessed by switching correct-incorrect lever identities after 8 consecutive correct choices. Transgenic male rats that lacked adult neurogenesis displayed an initial deficit in discriminating the correct and incorrect levers, but they were not impaired at reversing behavior when the reward contingencies switched. When reward was withheld after a correct lever choice, neurogenesis-deficient rats were more likely to choose the incorrect lever on the subsequent trial. Also, rats with intact neurogenesis were more sensitive to reward at the incorrect lever. Differences were not observed in control transgenic rats that had intact neurogenesis. These results identify a novel role for neurogenesis in learning about uncertain, probabilistic rewards. Altered sensitivity to reward and negative feedback furthermore implicates neurogenesis in cognitive phenotypes associated with mood disorders such as depression.
Adult hippocampal neurogenesis is implicated in a number of disorders where reward processes are disrupted but whether new neurons regulate specific reward behaviors remains unknown. We find that blocking neurogenesis in rats reduces activation of the ventral dentate gyrus and causes a profound aversion for delayed rewards. Delay-based decision-making restructured dendrites and spines in adultborn neurons, consistent with activity-dependent neuronal recruitment. These findings identify a novel role for neurogenesis in decisions about future rewards, which is compromised in disorders where shortsighted gains are preferred at the expense of long-term health. MAIN TEXTAdult neurogenesis in the dentate gyrus (DG) subregion of the hippocampus has been implicated in psychiatric disorders such as depression 1 but it remains unclear exactly which behavioral processes depend on new neurons, due to the complex and heterogeneous nature of the disorder. For example, one of the core symptoms of depression is anhedonia, often defined as diminished pleasure or interest in pleasurable activities 2 . However, many behavioral processes are subsumed under this broad definition 3 . Relative to controls, depressed patients place less value on future rewards, which may shift behaviors away from optimal, but delayed, outcomes 4 . Altered prospective behaviors may result from hippocampal deficits. Indeed, hippocampal activity patterns reflect future-oriented behaviors in both rodents 5-7 and humans 8,9 , amnesics have an impoverished imagination of possible future events 10 and hippocampal damage biases humans 11,12 and animals [13][14][15] towards immediately-available rewards, at the expense of larger, but delayed, rewards. Whether adult neurogenesis contributes to choices about future rewards is unknown. However, blocking neurogenesis in mice reduces sucrose preference 16 , consistent with a possible role in the anhedonic symptoms of depression.To test the role of adult neurogenesis in future reward choice, we took advantage of the transgenic GFAP-TK rat model to deplete neurogenesis 17 , and operant tasks that have been optimized for rats. As measured by the immature neuronal marker, DCX, neurogenesis was reduced in valganciclovirtreated (VGCV) TK rats by 94% in the dorsal DG and 77% in the ventral DG, compared to wild type (WT) rats (Fig. 1A-F). Blockade of neurogenesis reduced the overall volume of the dentate granule cell layer, consistent with DG atrophy in depressed patients 18,19 , but was without noticeable effect on subventricular zone neurogenesis, likely due to faster recovery in this neurogenic region during the VGCV-free period of operant testing (Supplementary Fig. 1 and Supplementary Fig. 2).Delayed rewards typically have less subjective value than immediately-available rewards, a phenomenon often referred to as delay discounting (DD) 20 . To determine if adult neurogenesis regulates the value of delayed rewards, we used a rodent DD paradigm where rats choose between a small reward (1 sugar pellet) that is delivered im...
Adult neurogenesis modifies hippocampal circuits and behavior, but removing newborn neurons does not consistently alter spatial processing, a core function of the hippocampus. Additionally, little is known about sex differences in neurogenesis since few studies have compared males and females. Since adult-born neurons regulate the stress response, we hypothesized that spatial functions may be more prominent under aversive conditions and may differ between males and females given sex differences in stress responding. We therefore trained intact and neurogenesis-deficient rats in the spatial water maze at temperatures that vary in their degree of aversiveness. In the standard water maze, ablating neurogenesis did not alter spatial learning in either sex. However, in cold water, ablating neurogenesis had divergent sex-dependent effects: relative to intact rats, male neurogenesis-deficient rats were slower to escape the maze and female neurogenesis-deficient rats were faster. Neurogenesis promoted temperature-related changes in search strategy in females, but it promoted search strategy stability in males. Females displayed greater recruitment (Fos expression) of the dorsal hippocampus than males, particularly in cold water. However, blocking neurogenesis did not alter Fos expression in either sex. Finally, morphologic analyses revealed greater experience-dependent plasticity in males. Adult-born neurons in males and females had similar morphology at baseline but training increased spine density and reduced presynaptic terminal size, specifically in males. Collectively, these findings indicate that adult-born neurons contribute to spatial learning in stressful conditions and they provide new evidence for sex differences in their behavioral functions.
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