Abstract
The hippocampus is functionally heterogeneous between the dorsal and ventral subfields with left–right asymmetry. To determine the possible location of contextual memory, we performed an inhibitory avoidance task to analyze synaptic plasticity using slice patch-clamp technique. The training bilaterally increased the AMPA/NMDA ratio at dorsal CA3–CA1 synapses, whereas the training did not affect the ratio at ventral CA3–CA1 synapses regardless of the hemisphere. Moreover, sequential recording of miniature excitatory postsynaptic currents and miniature inhibitory postsynaptic currents from the same CA1 neuron clearly showed learning-induced synaptic plasticity. In dorsal CA1 neurons, the training dramatically strengthened both excitatory and inhibitory postsynaptic responses in both hemispheres, whereas the training did not promote the plasticity in either hemisphere in ventral CA1 neurons. Nonstationary fluctuation analysis further revealed that the training bilaterally increased the number of AMPA or GABAA receptor channels at dorsal CA1 synapses, but not at ventral CA1 synapses, suggesting functional heterogeneity of learning-induced receptor mobility. Finally, the performance clearly impaired by the bilateral microinjection of plasticity blockers in dorsal, but not ventral CA1 subfields, suggesting a crucial role for contextual learning. The quantification of synaptic diversity in specified CA1 subfields may help us to diagnose and evaluate cognitive disorders at the information level.
Highlights
The hippocampus is functionally heterogeneous between the dorsal and ventral subfields (Fanselow and Dong 2010), with left–right asymmetry (Shinohara et al 2013)
At ventral CA3–CA1 synapses, the main effects of training (F1,39 = 0.960, P = 0.22), laterality (F1,39 = 1.641, P = 0.21), and interaction (F1,39 = 0.022, P = 0.88) were not significant (Fig. 2E,F). These results suggest that the training bilaterally strengthened AMPA receptor-mediated CA3–CA1 synapses in dorsal CA1 neurons, regardless of the hemisphere, but not in ventral CA1 neurons
Rat hippocampus is known to contain approximately 311 500 CA1 pyramidal neurons, receiving 13 059-28 697 CA3–CA1 synapses and up to 1 742 temporoammonic synapses from entorhinal cortex per single neuron (Bezaire and Soltesz 2013). Both structural and functional heterogeneity are known in dorso/ventral or left /right CA1 neurons, the location of learning-induced synaptic plasticity has not been specified in the broad CA1 area
Summary
The hippocampus is functionally heterogeneous between the dorsal and ventral subfields (Fanselow and Dong 2010), with left–right asymmetry (Shinohara et al 2013). Using an inhibitory avoidance (IA) task with a hippocampus-dependent contextual learning paradigm (Izquierdo et al 1998), we previously found that contextual learning requires synaptic plasticity for both 2184 | Cerebral Cortex, 2019, Vol 29, No 5 excitatory and inhibitory inputs at CA1 synapses (Mitsushima et al 2011, 2013). Since learning is known to modulate both excitatory and inhibitory synaptic plasticity in key brain areas such as hippocampus (Mitsushima et al 2013), amygdala (Lin et al 2011; Ganea et al 2015), or cortical areas (Ghosh et al 2015, 2016; Kida et al 2016), this approach may help us to diagnose and evaluate cognitive disorders in multiple brain regions
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