Feedforward and feedback projections of caudal belt and parabelt areas of auditory cortex: refining the hierarchical model

Hackett, Troy A.; Mothe, Lisa A. de la; Camalier, Corrie R.; Falchier, Arnaud; Lakatos, Péter L.; Kajikawa, Yoshinao; Schroeder, Charles E.

doi:10.3389/fnins.2014.00072

Cited by 57 publications

(56 citation statements)

References 95 publications

(163 reference statements)

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“…These assays were performed in parallel in adult mouse and macaque monkey tissue, in support of the present study of mice and prior studies of monkeys (Balaram et al 2011; Hackett and de la Mothe 2009; Hackett et al 2014). Antibody specificity was tested by incubating each antibody with a 10× concentration of the control protein provided by the manufacturer, when available.…”

Section: Methodssupporting

confidence: 55%

“…NeuN (Fox-3) is one of many members of the RNA-binding protein family (Darnell 2013). Although these proteins are mainly involved in the regulation of mRNA, Fox-3/NeuN is widely used as a neuron-specific marker in adult and developing brain across species (Arellano et al 2012; Fuentes-Santamaria et al 2013; Hackett et al 2014; Kim et al 2009). Antibodies for NeuN produce strong somatic labeling of neurons in most brain areas.…”

Section: Methodsmentioning

confidence: 99%

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Differential maturation of vesicular glutamate and GABA transporter expression in the mouse auditory forebrain during the first weeks of hearing

et al. 2015

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Vesicular transporter proteins are an essential component of the presynaptic machinery that regulates neurotransmitter storage and release. They also provide a key point of control for homeostatic signaling pathways that maintain balanced excitation and inhibition following changes in activity levels, including the onset of sensory experience. To advance understanding of their roles in the developing auditory forebrain, we tracked the expression of the vesicular transporters of glutamate (VGluT1, VGluT2) and GABA (VGAT) in primary auditory cortex (A1) and medial geniculate body (MGB) of developing mice (P7, P11, P14, P21, adult) before and after ear canal opening (~P11–P13). RNA sequencing, in situ hybridization, and immunohistochemistry were combined to track changes in transporter expression and document regional patterns of transcript and protein localization. Overall, vesicular transporter expression changed the most between P7 and P21. The expression patterns and maturational trajectories of each marker varied by brain region, cortical layer, and MGB subdivision. VGluT1 expression was highest in A1, moderate in MGB, and increased with age in both regions. VGluT2 mRNA levels were low in A1 at all ages, but high in MGB, where adult levels were reached by P14. VGluT2 immunoreactivity was prominent in both regions. VGluT1+ and VGluT2+ transcripts were co-expressed in MGB and A1 somata, but co-localization of immunoreactive puncta was not detected. In A1, VGAT mRNA levels were relatively stable from P7 to adult, while immunoreactivity increased steadily. VGAT+ transcripts were rare in MGB neurons, whereas VGAT immunoreactivity was robust at all ages. Morphological changes in immunoreactive puncta were found in two regions after ear canal opening. In the ventral MGB, a decrease in VGluT2 puncta density was accompanied by an increase in puncta size. In A1, peri-somatic VGAT and VGluT1 terminals became prominent around the neuronal somata. Overall, the observed changes in gene and protein expression, regional architecture, and morphology relate to—and to some extent may enable— the emergence of mature sound-evoked activity patterns. In that regard, the findings of this study expand our understanding of the presynaptic mechanisms that regulate critical period formation associated with experience-dependent refinement of sound processing in auditory forebrain circuits.

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Section: Methodssupporting

confidence: 55%

Section: Methodsmentioning

confidence: 99%

Differential maturation of vesicular glutamate and GABA transporter expression in the mouse auditory forebrain during the first weeks of hearing

et al. 2015

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“…According to this classic model, primary auditory cortex (AI) and adjacent cortex (areas R and RT) form the core region, surrounded by belt, and then parabelt regions. Neuroanatomical tracing studies demonstrate that each area has strong bidirectional connectivity with adjacent areas such that core areas are directly interconnected with their neighboring belt, but have sparse interconnections with parabelt areas (for review, see Jones, 2003; Hackett et al, 2014). More complex connectivity patterns are currently being characterized that refine this simplified scheme, including feedforward projections from parabelt to belt (Hackett et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Neuroanatomical tracing studies demonstrate that each area has strong bidirectional connectivity with adjacent areas such that core areas are directly interconnected with their neighboring belt, but have sparse interconnections with parabelt areas (for review, see Jones, 2003; Hackett et al, 2014). More complex connectivity patterns are currently being characterized that refine this simplified scheme, including feedforward projections from parabelt to belt (Hackett et al, 2014). Further confounding the classic serial core-belt-parabelt model of auditory cortical connectivity are the complex parallel pathways emanating from the medial geniculate complex (Jones, 2003).…”

Section: Introductionmentioning

confidence: 99%

Functional organization of human auditory cortex: Investigation of response latencies through direct recordings

et al. 2014

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The model for functional organization of human auditory cortex is in part based on findings in non-human primates, where the auditory cortex is hierarchically delineated into core, belt and parabelt fields. This model envisions that core cortex directly projects to belt, but not to parabelt, whereas belt regions are a major source of direct input for auditory parabelt. In humans, the posteromedial portion of Heschl’s gyrus (HG) represents core auditory cortex, whereas the anterolateral portion of HG and the posterolateral superior temporal gyrus (PLST) are generally interpreted as belt and parabelt, respectively. In this scheme, response latencies can be hypothesized to progress in serial fashion from posteromedial to anterolateral HG to PLST. We examined this hypothesis by comparing response latencies to multiple stimuli, measured across these regions using simultaneous intracranial recordings in neurosurgical patients. Stimuli were 100 Hz click trains and the speech syllable /da/. Response latencies were determined by examining event-related band power in the high gamma frequency range. The earliest responses in auditory cortex occurred in posteromedial HG. Responses elicited from sites in anterolateral HG were neither earlier in latency from sites on PLST, nor more robust. Anterolateral HG and PLST exhibited some preference for speech syllable stimuli compared to click trains. These findings are not supportive of a strict serial model envisioning principal flow of information along HG to PLST. In contrast, data suggest that a portion of PLST may represent a relatively early stage in the auditory cortical hierarchy.

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“…HACKETT temporal area), the insula, and poorly defined areas of the circular sulcus, such as Pro, part of which extends to the temporal pole. However, there is also substantial overlap of rostral and caudal areas of the belt and parabelt along this axis, and the connections with other cortical and sensory regions can be patchy, overlapping, or interdigitating Pandya, 1978, 1994;Galaburda and Pandya, 1983;Cipolloni and Pandya, 1985;Barnes and Pandya, 1992;Cusick et al, 1995;Seltzer et al, 1996;Hackett et al, 1998aHackett et al, , 2014. Laterally, the principal connections of the auditory (belt, parabelt) and auditory-related areas of the STG are with areas in the fundus and upper bank of the STS, known as the superior temporal polysensory region (STP).…”

mentioning

confidence: 99%

Anatomic organization of the auditory cortex

Hackett

2015

The Human Auditory System - Fundamental Organization and Clinical Disorders

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Feedforward and feedback projections of caudal belt and parabelt areas of auditory cortex: refining the hierarchical model

Cited by 57 publications

References 95 publications

Differential maturation of vesicular glutamate and GABA transporter expression in the mouse auditory forebrain during the first weeks of hearing

Differential maturation of vesicular glutamate and GABA transporter expression in the mouse auditory forebrain during the first weeks of hearing

Functional organization of human auditory cortex: Investigation of response latencies through direct recordings

Anatomic organization of the auditory cortex

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