Impaired Development and Competitive Refinement of the Cortical Frequency Map in Tumor Necrosis Factor- -Deficient Mice

Yang, Sungchil; Zhang, Li S.; Gibboni, Robert; Weiner, Benjamin; Bao, Shaowen

doi:10.1093/cercor/bht053

Cited by 16 publications

(15 citation statements)

References 59 publications

(96 reference statements)

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“…Through these effects, TNFα contributes to synaptic scaling, a form of homeostatic plasticity by which a population of synapses collectively adjusts its strength to long-term variations in network activity, e.g. during plastic rearrangement of sensory circuits 58,59 . TNFα also affects synaptic strength through regulation of astrocyte glutamate release ( Fig.…”

Section: Astrocyte-synapse Communication In Synaptic Plasticitymentioning

confidence: 99%

Astrocyte function from information processing to cognition and cognitive impairment

2019

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Astrocytes serve important roles that affect recruitment and function of neurons at the local and network levels. Here we review the contributions of astrocyte signaling to synaptic plasticity, neuronal network oscillations and memory function. The roles played by astrocytes are not fully understood, but astrocytes seem to contribute to memory consolidation and to mediate the effects of vigilance and arousal on memory performance. Understanding the role of astrocytes in cognitive processes may also advance our understanding of how these processes go awry in pathological conditions. Indeed, abnormal astrocytic signaling can cause or contribute to synaptic and network imbalances, leading to cognitive impairment. We discuss evidence for this from animal models of Alzheimer's disease and multiple sclerosis, and from animal studies of sleep deprivation and drug abuse and addiction. Understanding the emerging roles of astrocytes in cognitive function and dysfunction will open up a large array of new therapeutic opportunities.

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Section: Astrocyte-synapse Communication In Synaptic Plasticitymentioning

confidence: 99%

Astrocyte function from information processing to cognition and cognitive impairment

2019

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“…A recent study of the role of homeostatic synaptic plasticity in the development and refinement of frequency representations in mouse primary auditory cortex used the tumor necrosis factor-α (TNF-α) knockout (KO), a mutant mouse with impaired homeostatic but normal Hebbian plasticity [137]. These mice develop weaker tonal responses and incomplete frequency representations.…”

Section: Interpreting Map Plasticitymentioning

confidence: 99%

“…For instance, within minutes following exposure to intense noise, spectral and temporal organization of sound-evoked inhibitory synaptic inputs are dysregulated, producing poorly selective ‘noisy’ receptive field organization [145]. Over the course of several weeks, AI neurons become re-tuned to sound frequencies bordering the cochlear lesion [64, 131] in a manner that may depend on homeostatic plasticity mechanisms [137] rather than associative plasticity mechanisms such as modulation from nucleus basalis [146]. (e) Additional work will be needed to unveil the specific homeostatic mechanisms that enable receptive field renormalization following auditory deafferentation.…”

Section: Figurementioning

confidence: 99%

Auditory map plasticity: diversity in causes and consequences

Schreiner

Polley

2014

Current Opinion in Neurobiology

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Auditory cortical maps have been a long-standing focus of studies that assess the expression, mechanisms, and consequences of sensory plasticity. Here we discuss recent progress in understanding how auditory experience transforms spatially organized sound representations at higher levels of the central auditory pathways. New insights into the mechanisms underlying map changes have been achieved and more refined interpretations of various map plasticity effects and their consequences in terms of behavioral corollaries and learning as well as other cognitive aspects have been offered. The systematic organizational principles of cortical sound processing remains a key-aspect in studying and interpreting the role of plasticity in hearing.

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“…Receptive fields were isolated using an automated filtering and thresholding algorithm as previously described (Insanally et al 2010;Köver et al 2013;Yang et al 2013). Briefly, receptive fields were smoothed with a 3 ϫ 3 median filter and thresholded at 20% of the maximum response.…”

Section: Methodsmentioning

confidence: 99%

“…Linear regression analysis of neurons with receptive fields completely contained within 1 and 74 kHz shows a highly significant negative correlation between CF and BW for all six animals (r ϭ Ϫ0.77, P Ͻ 0.0001), showing narrower tuning BW for neurons in the UVF range. Interestingly, experience in multifrequency enriched environments can result in narrower frequency tuning (Köver et al 2013;Yang et al 2013).…”

Section: Rat Vocalizations Are Predominately Ultrasonicmentioning

confidence: 99%

Experience-dependent overrepresentation of ultrasonic vocalization frequencies in the rat primary auditory cortex

Kim

Bao

2013

Journal of Neurophysiology

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Kim H, Bao S. Experience-dependent overrepresentation of ultrasonic vocalization frequencies in the rat primary auditory cortex. J Neurophysiol 110: 1087-1096. First published June 5, 2013 doi:10.1152/jn.00230.2013.-Cortical sensory representation is highly adaptive to the environment, and prevalent or behaviorally important stimuli are often overrepresented. One class of such stimuli is speciesspecific vocalizations. Rats vocalize in the ultrasonic range Ͼ30 kHz, but cortical representation of this frequency range has not been systematically examined. We recorded in vivo cortical electrophysiological responses to ultrasonic pure-tone pips, natural ultrasonic vocalizations, and pitch-shifted vocalizations to assess how rats represent this ethologically relevant frequency range. We find that nearly 40% of the primary auditory cortex (AI) represents an octave-wide band of ultrasonic vocalization frequencies (UVFs; 32-64 kHz) compared with Ͻ20% for other octave bands Ͻ32 kHz. These UVF neurons respond preferentially and reliably to ultrasonic vocalizations. The UVF overrepresentation matures in the cortex before it develops in the central nucleus of inferior colliculus, suggesting a cortical origin and corticofugal influences. Furthermore, the development of cortical UVF overrepresentation depends on early acoustic experience. These results indicate that natural sensory experience causes large-scale cortical map reorganization and improves representations of species-specific vocalizations.

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Impaired Development and Competitive Refinement of the Cortical Frequency Map in Tumor Necrosis Factor- -Deficient Mice

Cited by 16 publications

References 59 publications

Astrocyte function from information processing to cognition and cognitive impairment

Astrocyte function from information processing to cognition and cognitive impairment

Auditory map plasticity: diversity in causes and consequences

Experience-dependent overrepresentation of ultrasonic vocalization frequencies in the rat primary auditory cortex

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