Damage to the hippocampal formation results in loss of recent memory and an inability to form and maintain new long-term memories. Consequently, there is agreement that the hippocampal formation plays a crucial role in memory consolidation, the process by which `labile' memory traces are transferred from hippocampal networks to permanent cortical storage over weeks or months. Understanding the mechanisms by which motivationally- salient memory traces are selected for consolidation is a major objective of systems-level neuroscience research. Dopamine (DA) is required for the maintenance of long-term potentiation in hippocampal networks. Disruption of ventral tegmental area (VTA) DA signaling to hippocampus leads to deficits in long-term memory formation. The VTA is also the primary source of DAergic projections to brain areas that serve important motivational roles, such as the nucleus accumbens and medial prefrontal cortex. For these reasons, it has been widely postulated that VTA DA signaling may serve as a `salience tag' for important hippocampus-dependent memories, designating them from long-term storage. Recent work from our lab has revealed distinct forms of VTA-hippocampal activity coordination during active spatial exploration compared to hippocampal `replay' of previous experience that occurs during quiet-wakefulness. This suggests that the role of VTA DA signaling in spatial learning may be switched rapidly depending on behavioral and/or neural state. However, a causal role for VTA-hippocampal activity coordination in spatial memory has not yet been established. In the work proposed here, VTA DA neurons will be optogenetically suppressed contingent on either active exploratory behavior or the detection of memory trace reactivation during quiet wakefulness. This closed-loop approach will allow selective, state-dependent disruption of VTA-hippocampal coordination. Consequent effects on spatial learning can then be directly attributed to the presence or absence of DA signaling during active exploration or mentation of previous experience. The intense scientific interest in understanding the mechanistic basis of memory consolidation is a result of its far-reaching clinical implications. Damage to the hippocampal formation can occur for a number of reasons including traumatic brain injury, type 2 diabetes, resection of epileptic foci, hippocampal infarct, and primary age- related neurodegenerative diseases. Hippocampal damage often results in temporally-graded retrograded amnesia and an inability to form new declarative memories. Better understanding the mechanisms by which the hippocampus is able to selectively gate important memories to long-term storage will inform the development of prosthetic devices to rescue memory function in individuals with hippocampal damage.
Damage to the hippocampal formation, resulting from brain injury or neurodegenerative disorders, leads to amnesia of recent experiences but leaves older memories intact. How does the brain decide which memories are important enough to warrant hippocampus-independent, long-term storage? The purpose of this study is to better understand how the brain assigns value to experiences in order to determine if they merit long-term storage, a critical step in the development of memory prostheses for correcting hippocampal damage.