Top‐down or bottom up: decreased stimulus salience increases responses to predictable stimuli of auditory thalamic neurons

Kommajosyula, Srinivasa P.; Cai, Rui; Bartlett, Edward E.; Caspary, Donald M.

doi:10.1113/jp277450

Cited by 11 publications

(30 citation statements)

References 145 publications

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“…However, since increased excitability usually leads to decreased timing fidelity, which was not the case in the older medial MGB neurons, it is possible the alterations in temporal acuity and firing rate could arise due to an interaction between general decreases in tonic inhibition and changes in the extracellular matrix at the level of the auditory thalamus (see section below). Alternatively, such changes could arise as a result of alterations in the corticothalamic feedback loops as suggested by the observation that MGB firing rates to degraded stimuli increase over repeated presentations (Kommajosyula, Cai, Bartlett, & Caspary, 2019). The age-related changes in the medial MGB are of particular interest as the medial MGB is thought to act as a polysensory, integrative center, combining information across auditory and non-auditory areas (see Rouiller (1997) and Winer (1992) for review).…”

Section: The Aged Auditory Thalamus Actively Transforms Temporally mentioning

confidence: 99%

Auditory temporal acuity improves with age in the male mouse auditory thalamus: A role for perineuronal nets?

Quraishe

Newman

Anderson³

2019

J of Neuroscience Research

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The ability to perceive and interpret environmental sound accurately is conserved across many species and is fundamental for understanding communication via vocalizations. Auditory acuity and temporally controlled neuronal firing underpin this ability. Deterioration in neuronal firing precision likely contributes to poorer hearing performance, yet the role of neural processing by key nuclei in the central auditory pathways is not fully understood. Here, we record from the auditory thalamus (medial geniculate body [MGB]) of young and middle‐aged, normally hearing male CBA/Ca mice. We report changes in temporal processing of auditory stimuli, with neurons recorded from ventral and medial MGB subdivisions of older animals more likely to synchronize to rapid temporally varying stimuli. MGB subdivisions also showed increased probability of neuronal firing and shorter response latencies to clicks in older animals. Histological investigation of neuronal extracellular specializations, perineuronal nets (PNNs) and axonal coats, in the MGB identified greater organization of PNNs around MGB neurons and the presence of axonal coats within older animals. This supports the observation that neural responses recorded from ventral and medial MGB of older mice were more likely to synchronize to temporally varying stimuli presented at faster repetition rates than those recorded from young adult animals. These changes are observed in animals with normal hearing thresholds, confirming that neural processing differs between the MGB subdivisions and such processing is associated with age‐related changes to PNNs. Understanding these age‐related changes and how they occur have important implications for the design of effective therapeutic interventions to improve speech intelligibility into later life.

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Section: The Aged Auditory Thalamus Actively Transforms Temporally mentioning

confidence: 99%

Auditory temporal acuity improves with age in the male mouse auditory thalamus: A role for perineuronal nets?

Quraishe

Newman

Anderson³

2019

J of Neuroscience Research

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“…Descending inputs from AC and RTN are less likely to show the sharpening of temporal tunings as the interaction of excitatory postsynaptic potential and inhibitory postsynaptic potential because Kv4.2 is less associated with these inputs. It has been shown that the interaction of top-down and bottom-up inputs was important for predicting the temporal structures of sound in MGB neurons ( Kommajosyula et al, 2019 ). The authors used salient (100% amplitude modulation) and less salient (25% amplitude modulation) sound sequences that were predictable or random order.…”

Section: Discussionmentioning

confidence: 99%

“…The thalamus receives sensory information from the lower brainstem centers and modulates and sends this information to the cortex ( Sherman and Guillery, 2002 ). Thus, the MGB relays neural information of the sound to the auditory cortex (AC) and segregates speech signals into different patterns for comprehension of the conveyed messages, interpretation of emotions associated with speech, and identification of the individual speaking ( Dagnino-Subiabre et al, 2009 ; Bartlett, 2013 ; Chen et al, 2019 ; Kommajosyula et al, 2019 ; Mihai et al, 2019 ). In the auditory information processing, such as in language interpretation, high timing resolution is important ( Dagnino-Subiabre et al, 2009 ), and bottom-up inputs from the inferior colliculus (IC) preserve temporal information of sound.…”

Section: Introductionmentioning

confidence: 99%

“…In the auditory information processing, such as in language interpretation, high timing resolution is important ( Dagnino-Subiabre et al, 2009 ), and bottom-up inputs from the inferior colliculus (IC) preserve temporal information of sound. However, if the sound is less salient, prediction from top-down inputs becomes important ( Kommajosyula et al, 2019 ). MGB neurons must have mechanisms for the integration of the top-down and bottom-up inputs.…”

Section: Introductionmentioning

confidence: 99%

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Kv4.2-Positive Domains on Dendrites in the Mouse Medial Geniculate Body Receive Ascending Excitatory and Inhibitory Inputs Preferentially From the Inferior Colliculus

et al. 2021

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The medial geniculate body (MGB) is the thalamic center of the auditory lemniscal pathway. The ventral division of MGB (MGV) receives excitatory and inhibitory inputs from the inferior colliculus (IC). MGV is involved in auditory attention by processing descending excitatory and inhibitory inputs from the auditory cortex (AC) and reticular thalamic nucleus (RTN), respectively. However, detailed mechanisms of the integration of different inputs in a single MGV neuron remain unclear. Kv4.2 is one of the isoforms of the Shal-related subfamily of potassium voltage-gated channels that are expressed in MGB. Since potassium channel is important for shaping synaptic current and spike waveforms, subcellular distribution of Kv4.2 is likely important for integration of various inputs. Here, we aimed to examine the detailed distribution of Kv4.2, in MGV neurons to understand its specific role in auditory attention. We found that Kv4.2 mRNA was expressed in most MGV neurons. At the protein level, Kv4.2-immunopositive patches were sparsely distributed in both the dendrites and the soma of neurons. The postsynaptic distribution of Kv4.2 protein was confirmed using electron microscopy (EM). The frequency of contact with Kv4.2-immunopositive puncta was higher in vesicular glutamate transporter 2 (VGluT2)-positive excitatory axon terminals, which are supposed to be extending from the IC, than in VGluT1-immunopositive terminals, which are expected to be originating from the AC. VGluT2-immunopositive terminals were significantly larger than VGluT1-immunopositive terminals. Furthermore, EM showed that the terminals forming asymmetric synapses with Kv4.2-immunopositive MGV dendritic domains were significantly larger than those forming synapses with Kv4.2-negative MGV dendritic domains. In inhibitory axons either from the IC or from the RTN, the frequency of terminals that were in contact with Kv4.2-positive puncta was higher in IC than in RTN. In summary, our study demonstrated that the Kv4.2-immunopositive domains of the MGV dendrites received excitatory and inhibitory ascending auditory inputs preferentially from the IC, and not from the RTN or cortex. Our findings imply that time course of synaptic current and spike waveforms elicited by IC inputs is modified in the Kv4.2 domains.

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“…Though the repetition enhancement described in human studies differs drastically on spatial and temporal scales from the phenomenon described here, we find that it similarly involves a sequential enhancement in the response to subsequent presentations of the standard (Figure 6C, 8D). Repetition enhancement has also been observed in the medial geniculate body in response to temporally degraded stimuli that are hypothesized to engage top-down resources to compensate for bottom-up acoustic information loss (Cai et al, 2016;Kommajosyula et al, 2019). Interestingly, this enhancement is reversed when cortico-thalamic pathways are blocked, further suggesting that repetition enhancement in the auditory system reflects a top-down phenomenon (Kommajosyula et al, 2021).…”

Section: Repetition Enhancement and Repetition Suppression In Icmentioning

confidence: 99%

Cortico-Fugal Regulation of Predictive Coding

Lesicko

Angeloni

Blackwell

et al. 2021

Preprint

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Sensory systems must account for both contextual factors and prior experience to adaptively engage with the dynamic external environment. In the central auditory system, neurons modulate their responses to sounds based on statistical context. These response modulations can be understood through a hierarchical predictive coding lens: responses to repeated stimuli are progressively decreased, in a process known as repetition suppression, whereas unexpected stimuli produce a prediction error signal. Prediction error incrementally increases along the auditory hierarchy from the inferior colliculus (IC) to the auditory cortex (AC), suggesting that these regions may engage in hierarchical predictive coding. A potential substrate for top-down predictive cues is the massive set of descending projections from the auditory cortex to subcortical structures. To assess the role of these projections in predictive coding, we optogenetically suppressed the auditory cortico-collicular feedback in awake mice while recording responses from IC neurons to stimuli designed to test prediction error and repetition suppression. Suppression of the cortico-collicular pathway led to a decrease in prediction error in IC. Repetition suppression was unaffected by cortico-collicular inactivation, suggesting that this metric may reflect fatigue of bottom-up sensory inputs rather than predictive processing. We also discovered populations of IC neurons that exhibit repetition enhancement, an increase in firing with stimulus repetition, and error suppression, a stronger response to a tone in a predictable rather than unpredictable context. Cortico-collicular suppression led to a decrease in repetition enhancement in the central nucleus and a reduction in error suppression in shell regions of IC. These changes in predictive coding metrics arose from bidirectional modulations in the response to the standard and deviant contexts, such that neurons in IC responded more similarly to each context in the absence of cortical input. Our results demonstrate that the auditory cortex provides cues about the statistical context of sound to subcortical brain regions via direct feedback, regulating processing of both prediction and repetition.

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Top‐down or bottom up: decreased stimulus salience increases responses to predictable stimuli of auditory thalamic neurons

Cited by 11 publications

References 145 publications

Auditory temporal acuity improves with age in the male mouse auditory thalamus: A role for perineuronal nets?

Auditory temporal acuity improves with age in the male mouse auditory thalamus: A role for perineuronal nets?

Kv4.2-Positive Domains on Dendrites in the Mouse Medial Geniculate Body Receive Ascending Excitatory and Inhibitory Inputs Preferentially From the Inferior Colliculus

Cortico-Fugal Regulation of Predictive Coding

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