Neuroscience
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Neuroglobin (Ngb) is a REST/NRSF-regulated protein, active in reactive oxygen species detoxification and cytochrome c inhibition, which provides a beneficial outcome in pathologies as Alzheimer's disease and strokes. Considering that oxidative stress and cell death are typical hallmarks of amyotrophic lateral sclerosis (ALS), we sought to explore Ngb's involvement along this disease progression. Ngb transcription was detected to be two-fold down-regulated in late-stage SODG93A mice, similarly as previously described for Alzheimer disease. ⋯ To look further into the link between Ngb and ALS, we generated a double mutant Ngb-/-SODG93A mouse model, which shows an earlier onset and severity of hind limb deficits. Mitochondria derived thereof showed an altered mean volume, granularity and Ca2+-induced swelling as compared to NgbWt/WtSODG93A mice. These results indicate Ngb to be involved in and affected by the SOD1G93A pathology, which could in part be attributed to its role in halting destabilizing events of mitochondrial swelling and phenotypes.
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Drug relapse after periods of abstinence is a common feature of substance abuse. Moreover, anxiety and other mood disorders are often co-morbid with substance abuse. Cholinergic receptors in the ventral tegmental area (VTA) are known to mediate drug-seeking and anxiety-related behavior in rodent models. ⋯ V. saline rats, displayed an anxiogenic response on day 14 of abstinence as reflected by decreased open arm time in the EPM. Furthermore, low doses of VTA mecamylamine (10 μg /side) or scopolamine (2.4 μg /side), that did not alter EPM behavior in cocaine naive rats, were sufficient to reverse the anxiogenic effects of cocaine abstinence. Together, these data point to an overlapping role of VTA cholinergic mechanisms to regulate relapse and mood disorder-related responses during cocaine abstinence.
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Explanations of memory-guided navigation in rodents typically suggest that cue- and place-based navigations are independent aspects of behavior and neurobiology. The results of many experiments show that hippocampal damage causes both anterograde and retrograde amnesia (AA; RA) for place memory, but only RA for cue memory. In the present experiments, we used a concurrent cue-place water task (CWT) to study the effects of hippocampal damage before or after training on cue- and place-guided navigation, and how cue and place memory interact in damaged and control rats. ⋯ By contrast to these anterograde effects, damage made after training causes RA for cue choice accuracy and latency to navigate to the correct cue. In addition, the extent of hippocampal damage predicted impairments in choice accuracy when lesions were made after training. These data extend previous work on the role of the hippocampus in cue and place memory-guided navigation, and show that the hippocampus plays an important role in both aspects of memory and navigation when present during the learning experience.
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Decision-making in the mammalian brain typically involves multiple brain structures within the midbrain, thalamus, striatum, limbic system, and cortex. Although task specific contributions of each brain region have been identified, neurons responding to reinforcement have been found throughout these structures. We sought to determine if any brain area, or cluster of areas, are the source of information, and if the fidelity of information varies among the areas. ⋯ Analysis of FPs prior to reward revealed most regions reflected the prior probability of reward. Lastly, analyses of information flow suggested reinforcement information does not originate within a single structure of the network, within the resolution afforded by FP recordings. These data suggest reward delivery information is rapidly distributed non-uniformly across the network, and there is no canonical flow of information about reward events in the recorded structures.
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Hippocampal oscillations, particularly theta (6-12 Hz) and gamma (30-90 Hz) frequency bands, play an important role in several cognitive functions. Theta and gamma oscillations show cross-frequency coupling (CFC), wherein the phase of theta rhythm modulates the amplitude of the gamma oscillation, and this CFC is believed to reflect cell assembly dynamics in cognitive processes. Previous studies have reported that CFC strength correlates with the learning process. ⋯ The enhanced coupling between theta and high-gamma oscillations (60-90 Hz) changed during the late stage of learning. In contrast, the coupling between theta and low-gamma oscillations (30-60 Hz) did not show any changes during learning. These results suggest that the coupling between theta and gamma bands occurs during rule learning and that high- and low-gamma bands play different roles in rule switching.