The hippocampus has been thought to process auditory information. However, the properties, pathway, and role of hippocampal auditory responses are unclear. With loose-patch recordings, we found that hippocampal neurons are mainly responsive to noise and are not tonotopically organized. Their latencies are shorter than those of primary auditory cortical (A1) neurons but longer than those of medial septal (MS) neurons, suggesting that hippocampal auditory information comes from MS neurons rather than from A1 neurons. Silencing the MS blocks both hippocampal auditory responses and memory of auditory fear conditioning trained with noise and tone. Auditory fear conditioning was associated with some cues but not with a specific frequency of sound, as demonstrated by animals trained with noise, 2.5-, 5-, 10-, 15-, or 30-kHz tones, and tested with these sounds. Therefore, the noise responses of hippocampal neurons have identified a population of neurons that can be associated with auditory fear conditioning.
Sex differences have been reported in a number of pain conditions. Women are more sensitive to most types of painful stimuli than men, and estrogen plays a key role in the sex differences in pain perception. However, it is unclear whether there is a sex difference in acidosis-evoked pain. We report here that both male and female rats exhibit nociceptive behaviors in response to acetic acid, with females being more sensitive than males. Local application of exogenous 17β-estradiol (E2) exacerbated acidosis-evoked nociceptive response in male rats. E2 and estrogen receptor (ER)-α agonist 1,3,5-Tris(4-hydroxyphenyl)-4-propyl-1H-pyrazole, but not ERβ agonist 2,3-bis(4-hydroxyphenyl)-propionitrile, replacement also reversed attenuation of the acetic acid-induced nociceptive response in ovariectomized females. Moreover, E2 can exert a rapid potentiating effect on the functional activity of acid-sensing ion channels (ASICs), which mediated the acidosis-induced events. E2 dose dependently increased the amplitude of ASIC currents with a 42.8 ± 1.6 nM of EC50. E2 shifted the concentration-response curve for proton upward with a 50.1% ± 6.2% increase of the maximal current response to proton. E2 potentiated ASIC currents via an ERα and ERK1/2 signaling pathway. E2 also altered acidosis-evoked membrane excitability of dorsal root ganglia neurons and caused a significant increase in the amplitude of the depolarization and the number of spikes induced by acidic stimuli. E2 potentiation of the functional activity of ASICs revealed a peripheral mechanism underlying this sex difference in acetic acid-induced nociception.
The hippocampus is known as a neuronal structure involved in learning, memory and spatial navigation using multi-sensory cues. However, the basic features of its response to acoustic stimuli without any behavioral tasks (conditioning) remains poorly studied. Here, we investigated the CA3 response to auditory stimuli using in vivo loose-patch recordings in awake and anesthetized C57 mice. Different acoustic stimuli in addition to broadband noise such as click, FM sound and pure tone were applied to test the response of CA3 in awake animals. It was found that the wakefulness of the animal is important for the recorded neurons to respond. The CA3 neurons showed a stronger response to broadband noise rather than the other type of stimuli which suggested that auditory information arrived at CA3 via broadband pathways. Finally, we investigated the excitatory and inhibitory inputs to CA3 neurons by using in vivo whole-cell voltage-clamp techniques with the membrane potential holding at −70 and 0 mV, respectively. In awake animals, the excitatory and inhibitory inputs CA3 neurons receive induced by noise are balanced by showing stable intervals and proportional changes of their latencies and peak amplitudes as a function of the stimulation intensities.
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