Currently, a number of genetic or virus-based approaches are
used to target dividing NSPCs or their progeny to reduce neurogenesis [53–56]. In addition, strategies using optogenetics have recently been developed to manipulate the contribution of new neurones to hippocampal circuit activity [57]. Initial experiments aiming to characterize the functional contribution of new neurones to hippocampus-dependent selleckchem behaviour predominantly used paradigms designed to test the function of the complete hippocampal circuitry (such as Morris water maze, contextual fear conditioning). However, more recent studies aimed to test more selectively the dentate circuitry by using tasks that specifically challenge this hippocampal subregion [55,58–60]. Guided by electrophysiological and computational selleck chemical data addressing the exact function of the DG, it was shown (using a number of gain- and loss-of-function strategies) that new neurones seem to be critically involved in a cognitive
functions called pattern separation, which in simple terms means that highly similar inputs are differentially represented in the output, which is potentially one of the key functions of the DG [55,59,60]. How new neurones contribute (or exert) this function remains poorly understood but it is believed that the period of heightened excitability that young neurones exhibit between 3 and 6 weeks after they are born may be crucial to fulfil this function
[41,43,44,61]. Be that as it may, it is not clear if indeed excitation generated by new neurones onto target pyramidal cells in CA3 is key to understanding their function or if new neurones rather shape the dentate circuitry and network activity by connecting to local neuronal cells such as hilar mossy cells or dentate GABAergic inhibitory neurones [19,41]. Future experiments aiming Abiraterone mouse to analyse in vivo network behaviour after manipulating the number of new neurones (or their activity) will help to further understand how newborn granule cells shape dentate connectivity and function. The finding that neurogenesis does not tamper off with the end of development but continues throughout life initiated a large number of studies using a variety of rodent disease models to study the effects of brain diseases on neurogenesis. Strikingly, a substantial number of psychiatric (e.g. models of major depression) and acute or chronic neurodegenerative diseases (e.g. models of stroke, Alzheimer’s disease, epilepsy) were found to have a profound effect on hippocampal neurogenesis [5].