The effects of pool shape manipulations on rat spatial memory acquired in the Morris water maze.

The Morris water maze is a popular task for examining spatial navigation and memory in rats. Historically, emphasis has been put on extramaze cues as the primary environmental feature guiding navigation and spatial memory formation. However, other features of the environment may also be involved. In this experiment, we trained rats on the spatial version of the Morris water maze over four days. A probe test was given 24 h after training, in which the shape of the pool either remained the same as during training or was changed to a different shape. Mass training of a new platform position in one training session was performed in a pool of one of these two shapes, with a second probe test being done 24 h afterward. The results showed that spatial training produces a spatial preference for the trained location in the probe test when the pool shape remains the same. However, changing the shape of the pool eliminates this preference. All groups learned the new platform position during mass training and also expressed a spatial preference for the mass-trained quadrant when tested 24 h later. The results from these experiments implicate the use of pool shape in guiding spatial navigation in the water maze and as a critical environmental feature represented in spatial memory.

A Specific Role of Hippocampal NMDA Receptors and Arc Protein in Rapid Encoding of Novel Environmental Representations and a More General Long-Term Consolidation Function.

Activation of the NMDA receptor (NMDAR) has been proposed to be a key event responsible for the structural changes that occur in neurons during learning and memory formation. It has been extensively studied yet no consensus has been reached on its mnemonic role as both NMDAR dependent and independent forms of learning have been observed. We investigated the role that hippocampal NMDAR have in rapid spatial learning and memory across training environments. Hippocampal NMDAR was blocked via intra-hippocampal injection of the competitive antagonist CPP. Groups of rats were pre-trained on a spatial version of the Morris water task, and then mass reversal training under NMDAR blockade occurred in the same or different training environments as pre-training. We measured expression of Arc protein throughout the main hippocampal subfields, CA1, CA3, and dentate gyrus, after mass-training. We observed that NMDAR blockade allowed for rapid spatial learning, but not consolidation, when the SUBJECTS used previously acquired environmental information. Interestingly, NMDAR blockade impaired rapid spatial learning when rats were mass-trained in a novel context. Arc protein expression in the dentate gyrus followed this pattern of NMDAR dependent spatial behavior, with high levels of expression observed after being trained in the new environment, and low levels when trained in the same environment. CPP significantly reduced Arc expression in the dentate gyrus. These results implicate dentate NMDAR in the acquisition of novel environmental information.