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《Current biology : CB》2021,31(24):5450-5461.e4
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Mark Mayford 《Philosophical transactions of the Royal Society of London. Series B, Biological sciences》2014,369(1633)
Understanding the molecular and cellular changes that underlie memory, the engram, requires the identification, isolation and manipulation of the neurons involved. This presents a major difficulty for complex forms of memory, for example hippocampus-dependent declarative memory, where the participating neurons are likely to be sparse, anatomically distributed and unique to each individual brain and learning event. In this paper, I discuss several new approaches to this problem. In vivo calcium imaging techniques provide a means of assessing the activity patterns of large numbers of neurons over long periods of time with precise anatomical identification. This provides important insight into how the brain represents complex information and how this is altered with learning. The development of techniques for the genetic modification of neural ensembles based on their natural, sensory-evoked, activity along with optogenetics allows direct tests of the coding function of these ensembles. These approaches provide a new methodological framework in which to examine the mechanisms of complex forms of learning at the level of the neurons involved in a specific memory. 相似文献
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Memory, defined as the storage and use of learned information in the brain, is necessary to modulate behavior and critical for animals to adapt to their environments and survive. Despite being a cornerstone of brain function, questions surrounding the molecular and cellular mechanisms of how information is encoded, stored, and recalled remain largely unanswered. One widely held theory is that an engram is formed by a group of neurons that are active during learning, which undergoes biochemical and physical changes to store information in a stable state, and that are later reactivated during recall of the memory. In the past decade, the development of engram labeling methodologies has proven useful to investigate the biology of memory at the molecular and cellular levels. Engram technology allows the study of individual memories associated with particular experiences and their evolution over time, with enough experimental resolution to discriminate between different memory processes: learning (encoding), consolidation (the passage from short-term to long-term memories), and storage (the maintenance of memory in the brain). Here, we review the current understanding of memory formation at a molecular and cellular level by focusing on insights provided using engram technology. 相似文献
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《Current biology : CB》2019,29(11):1885-1894.e4
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《Cell reports》2023,42(1):111962
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Mehmet Bostancıklıoğlu 《Journal of cellular physiology》2020,235(2):836-847
How are memories stored and retrieved? It was one of the most discussed questions in the past century by neuroscientists. Leading studies of the period brought two different explanations to this question: The first statement considers memory as a physiological change in the brain and suggest that the retrieval of memory is only occurred by the same physiologic changes observed during the memory formation, while the second suggests that memory is a psychic mood stored in mind and the retrieval of memory is occurred by mystical energy fluctuations. Although the exact reason and the pathogenesis of Alzheimer's disease have not yet been fully understood, the approaches that centered the retrieval strategy of lost memory constitutes the basis of the treatment strategies in Alzheimer's disease today. The majority of treatment studies has based on the manipulation of the cholinergic system; however, although serotonin has mnemonic effects, its role in the pathogenesis of Alzheimer's disease has not been investigated as much as the cholinergic system. Here we show how serotonin affects the pathogenesis of Alzheimer's disease in a comprehensive perspective and we suggest that the optogenetics manipulation of serotonin nuclei retrieve the lost memory by closing the inward-rectifier potassium channel Kir2 on the memory engram cells. Also, we raise the possible effects of serotonin on the memory engram cells and the interactions between the amyloid-centric hypothesis of Alzheimer's disease and the memory engram hypothesis to explain the pathophysiology of memory loss in Alzheimer's disease. 相似文献
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Both field and laboratory studies demonstrate that hummingbirds (Apodiformes, Trochilidae) have exceptional spatial memory. The complexity of spatial-temporal information that hummingbirds must retain and use daily is probably subserved by the hippocampal formation (HF), and therefore, hummingbirds should have a greatly expanded HF. Here, we compare the relative size of the HF in several hummingbird species with that of other birds. Our analyses reveal that the HF in hummingbirds is significantly larger, relative to telencephalic volume, than any bird examined to date. When expressed as a percentage of telencephalic volume, the hummingbird HF is two to five times larger than that of caching and non-caching songbirds, seabirds and woodpeckers. This HF expansion in hummingbirds probably underlies their ability to remember the location, distribution and nectar content of flowers, but more detailed analyses are required to determine the extent to which this arises from an expansion of HF or a decrease in size of other brain regions. 相似文献
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Jessica Rodgers Beatriz Bano&#x;Otalora Mino D C Belle Sarika Paul Rebecca Hughes Phillip Wright Richard McDowell Nina Milosavljevic Patrycja Orlowska&#x;Feuer Franck P Martial Jonathan Wynne Edward R Ballister Riccardo Storchi Annette E Allen Timothy Brown Robert J Lucas 《EMBO reports》2021,22(5)
There is no consensus on the best inhibitory optogenetic tool. Since Gi/o signalling is a native mechanism of neuronal inhibition, we asked whether Lamprey Parapinopsin (“Lamplight”), a Gi/o‐coupled bistable animal opsin, could be used for optogenetic silencing. We show that short (405 nm) and long (525 nm) wavelength pulses repeatedly switch Lamplight between stable signalling active and inactive states, respectively, and that combining these wavelengths can be used to achieve intermediate levels of activity. These properties can be applied to produce switchable neuronal hyperpolarisation and suppression of spontaneous spike firing in the mouse hypothalamic suprachiasmatic nucleus. Expressing Lamplight in (predominantly) ON bipolar cells can photosensitise retinas following advanced photoreceptor degeneration, with 405 and 525 nm stimuli producing responses of opposite sign in the output neurons of the retina. We conclude that bistable animal opsins can co‐opt endogenous signalling mechanisms to allow optogenetic inhibition that is scalable, sustained and reversible. 相似文献
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《Developmental cell》2021,56(24):3393-3404.e7
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