Sialyltransferase ST3Gal IV deletion protects against temporal lobe epilepsy.

Temporal lobe epilepsy (TLE) often becomes refractory, and patients with TLE show a high incidence of psychiatric symptoms, including anxiety and depression. Therefore, it is necessary to identify molecules that were previously unknown to contribute to epilepsy and its associated disorders. We previously found that the sialyltransferase ST3Gal IV is up-regulated within the neural circuits through which amygdala-kindling stimulation propagates epileptic seizures. In contrast, this study demonstrated that kindling stimulation failed to evoke epileptic seizures in ST3Gal IV-deficient mice. Furthermore, approximately 80% of these mice failed to show tonic-clonic seizures with stimulation, whereas all littermate wild-type mice showed tonic-clonic seizures. This indicates that the loss of ST3Gal IV does not cause TLE in mice. Meanwhile, ST3Gal IV-deficient mice exhibited decreased acclimation in the open field test, increased immobility in the forced swim test, enhanced freezing during delay auditory fear conditioning, and sleep disturbances. Thus, the loss of ST3Gal IV modulates anxiety-related behaviors. These findings indicate that ST3Gal IV is a key molecule in the mechanisms underlying anxiety - a side effect of TLE - and may therefore also be an effective target for treating epilepsy, acting through the same circuits.

Infusion of growth hormone into the hippocampus induces molecular and behavioral responses in mice.

Growth hormone (GH) has been implicated in a variety of brain functions, including neural development, cognition, and neuroprotection. The biological effects of GH are known to rely on the binding of GH to the GH receptor (GHR), yet the resulting signals in the brain remain poorly understood. The present study investigated the effects of hippocampal infusions of recombinant GH and a GHR antagonist on the expression of immediate early genes (IEGs) and behavioral responses in mice. The infusions induced differential expression of Arc, Nr4a1, and Npas4 mRNAs among the IEGs. The infusions also elicited differential behavioral responses, such as varied levels of spontaneous locomotion, self-grooming, and frequency of access to the corner fields in the open-field test. Polynomial regression analyses and canonical discriminant analyses between gene expression and behavioral changes demonstrated that the expression level of Arc mRNA was strongly correlated with locomotor activity level (r = 0.71 and 0.92 on days 8 and 10, respectively) and that the correlation was completely discriminable between drugs (error rate = 0%). This analysis also revealed that a decrease in Npas4 mRNA was negatively correlated with the number of corner accesses (r = -0.63) and that this correlation was partially discriminable between drugs (error rate = 16.67%). Taken together, these results suggest that the GH-GHR complex modulates Arc and Npas4 signaling, which affects spontaneous locomotor and exploratory behaviors.