Neuropsychological and neurophysiological studies have emphasized the role of the prefrontal cortex (PFC) in maintaining information about the temporal order of events or items for upcoming actions. However, the medial temporal lobe (MTL) has also been considered critical to bind individual events or items to their temporal context in episodic memory. Here we characterize the contributions of these brain areas by comparing single-unit activity in the dorsal and ventral regions of macaque lateral PFC (d-PFC and v-PFC) with activity in MTL areas including the hippocampus (HPC), entorhinal cortex, and perirhinal cortex (PRC) as well as in area TE during the encoding phase of a temporal-order memory task. The v-PFC cells signaled specific items at particular time periods of the task. By contrast, MTL cortical cells signaled specific items across multiple time periods and discriminated the items between time periods by modulating their firing rates. Analysis of the temporal dynamics of these signals showed that the conjunctive signal of item and temporal-order information in PRC developed earlier than that seen in v-PFC. During the delay interval between the two cue stimuli, while v-PFC provided prominent stimulus-selective delay activity, MTL areas did not. Both regions of PFC and HPC exhibited an incremental timing signal that appeared to represent the continuous passage of time during the encoding phase. However, the incremental timing signal in HPC was more prominent than that observed in PFC. These results suggest that PFC and MTL contribute to the encoding of the integration of item and timing information in distinct ways.
Background: Orexin can facilitate emergence after general anaesthesia via multiple neural pathways. Dopaminergic neurones in the ventral tegmental area (VTA) participate in behavioural arousal from anaesthesia. We investigated the regulation of dopaminergic VTA neurones by orexinergic neurones during emergence from general anaesthesia. Methods: Orexins were microinjected into the VTA to determine the effects on isoflurane anaesthesia induction, emergence, and maintenance. Orexin receptors and dopaminergic neurones in the VTA were identified using immunofluorescence. Orexinergic terminals in the VTA were optogenetically regulated to detect the endogenous orexinmediated regulation of dopaminergic neurones during anaesthesia in Hcrt cre rats. Results: Injection of orexin-A (100 pmol) into the VTA reduced emergence time [from 949 (118) to 727 (101) s; P¼0.0058] and reduced the electroencephalographic burstesuppression ratio (BSR) (26.6 [10.2]% vs 44.3 [6.8]%; P¼0.0027) during isoflurane anaesthesia. The percentage of dopaminergic neurones that expressed either orexin-1 receptor or orexin-2 receptor was 73.4 (5.0)% and 74.4 (62.4)%, respectively. Optogenetic activation of orexinergic projections to the VTA reduced the BSR (from 40.5 [2.7]% to 22.4 [11.8]%; P¼0.0019) and facilitated emergence (915 [89] vs 685 [68] s; P¼0.0026), whereas optical inhibition prolonged the time to wakefulness (from 941 [92] to 1279 [250] s; P¼0.011). Dopaminergic neurones in the VTA showed increased firing frequency (387 [78]% of control, P¼0.005) after bath application of orexin-A. Conclusions: Orexin promotes emergence from isoflurane anaesthesia through activation of dopaminergic neurones in the VTA.
The ability to use stored information in a highly flexible manner is a defining feature of the declarative memory system. However, the neuronal mechanisms underlying this flexibility are poorly understood. To address this question, we recorded single-unit activity from the hippocampus of 2 nonhuman primates performing a newly devised task requiring the monkeys to retrieve long-term item-location association memory and then use it flexibly in different circumstances. We found that hippocampal neurons signaled both mnemonic information representing the retrieved location and perceptual information representing the external circumstance. The 2 signals were combined at a single-neuron level to construct goal-directed information by 3 sequentially occurring neuronal operations (e.g., convergence, transference, and targeting) in the hippocampus. Thus, flexible use of knowledge may be supported by the hippocampal constructive process linking memory and perception, which may fit the mnemonic information into the current situation to present manageable information for a subsequent action.
There are no effective treatments for stroke. The activation of endogenous protective mechanisms is a promising therapeutic approach, which evokes the intrinsic ability of the brain to protect itself. Accumulated evidence strongly suggests that electroacupuncture (EA) pretreatment induces rapid tolerance to cerebral ischemia. With regard to mechanisms underlying ischemic tolerance induced by EA, many molecules and signaling pathways are involved, such as the endocannabinoid system, although the exact mechanisms have not been fully elucidated. In the current study, we employed mutant mice, neuropharmacology, microdialysis, and virus transfection techniques in a middle cerebral artery occlusion (MCAO) model to explore the cell-specific and brain region-specific mechanisms of EA-induced neuroprotection. EA pretreatment resulted in increased ambient endocannabinoid (eCB) levels and subsequent activation of ischemic penumbral astroglial cannabinoid type 1 receptors (CB1R) which led to moderate upregulation of extracellular glutamate that protected neurons from cerebral ischemic injury. These findings provide a novel cellular mechanism of EA and a potential therapeutic target for ischemic stroke.
For living organisms, the ability to acquire information regarding the external space around them is critical for future actions. While the information must be stored in an allocentric frame to facilitate its use in various spatial contexts, each case of use requires the information to be represented in a particular self‐referenced frame. Previous studies have explored neural substrates responsible for the linkage between self‐referenced and allocentric spatial representations based on findings in rodents. However, the behaviors of rodents are different from those of primates in several aspects; for example, rodents mainly explore their environments through locomotion, while primates use eye movements. In this review, we discuss the brain mechanisms responsible for the linkage in nonhuman primates. Based on recent physiological studies, we propose that two types of neural substrates link the first‐person perspective with allocentric coding. The first is the view‐center background signal, which represents an image of the background surrounding the current position of fixation on the retina. This perceptual signal is transmitted from the ventral visual pathway to the hippocampus (HPC) via the perirhinal cortex and parahippocampal cortex. Because images that share the same objective‐position in the environment tend to appear similar when seen from different self‐positions, the view‐center background signals are easily associated with one another in the formation of allocentric position coding and storage. The second type of neural substrate is the HPC neurons' dynamic activity that translates the stored location memory to the first‐person perspective depending on the current spatial context.
The Siberian tiger (Panthera tigris altaica) is one of the largest felines, and is mainly found in Russian Far East, northeast of China and north of Korea. Currently, there are approximately 400 wild Siberian tigers globally, with only a few of these in China (Peng et al., 2020).Therefore, they are listed as level I protected animals by the Chinese government, are included in the Convention on International Trade
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