Individual mediodorsal thalamic neurons project to multiple areas of the rat prefrontal cortex: A single neuron‐tracing study using virus vectors

Kuramoto, Eiichi; Pan, Shixiu; Furuta, Takeshi; Tanaka, Yasuhiro; Iwai, Haruki; Yamanaka, Akira; Ohno, Sho; Kaneko, Takeshi; Goto, Tetsuya; Hioki, Hiroyuki

doi:10.1002/cne.24054

Cited by 111 publications

(88 citation statements)

References 59 publications

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“…Recently, single‐cell tracing studies of the above three higher‐order thalamic regions demonstrated that single neurons of these thalamic regions formed multiple axon arbors in the different cortical areas (Ohno et al, ; Nakamura et al, ; Kuramoto et al, ). Accordingly, the formation of multiple axon arbors may be common characteristics as higher‐order thalamic nuclei neurons.…”

Section: Discussionmentioning

confidence: 99%

“…Thus, the corticothalamic excitatory input may function as a driver input for the ventral Sm. Similarly, several thalamic regions, such as the anterior region of the posterior nuclei, the lateral subdivision of the lateral posterior nucleus, and mediodorsal nucleus, have been reported to show few or very weak VGluT2 immunoreactivity (Kaneko, Fujiyama, & Hioki, ; Ohno et al, ; Nakamura, Hioki, Furuta, & Kaneko, ; Kuramoto et al, ). These three thalamic regions have been considered to be higher‐order thalamic nuclei (Varela, ), and suggested to receive driver inputs from layer 5 of the cerebral cortex (Groenewegen, ; Bourassa & Deschênes, ; Veinante, Laballée, & Deschênes, ).…”

Section: Discussionmentioning

confidence: 99%

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Dorsal and ventral parts of thalamic nucleus submedius project to different areas of rat orbitofrontal cortex: A single neuron‐tracing study using virus vectors

Kuramoto

Iwai

Yamanaka

et al. 2017

J of Comparative Neurology

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The rodent orbitofrontal cortex is involved in a variety of cognitive and behavioral functions that require thalamic input to be successfully expressed. Although the thalamic nucleus submedius (Sm) is a major source of afferents to the orbitofrontal cortex, thalamocortical projection from the Sm has not been fully elucidated. In the present study, we first divided the rat Sm into dorsal and ventral parts according to the distribution of vesicular glutamate transporter 2-immunoreactive varicosities, which were somatosensory afferents from the brain stem. Subsequently we investigated dendritic and axonal arborizations of individual dorsal and ventral Sm neurons by visualizing the processes with Sindbis virus vectors expressing membrane-targeted fluorescent proteins. The number of dendritic processes of ventral Sm neurons was greater than that of dorsal Sm neurons. In the cerebral cortex, all the reconstructed Sm neurons sent axons primarily to layers 2-5. Interestingly, dorsal Sm neurons formed a single axon arbor exclusively within the ventrolateral orbital area, whereas ventral Sm neurons made two axon arbors in the lateral orbital and ventral orbital areas simultaneously. The spread of each axon arbor was 500-1000 µm in diameter in the direction tangential to the cortical surface. These results indicate that the dorsal and ventral Sm comprise two distinct thalamocortical pathways. The dorsal Sm pathway relay somatosensory information to the ventrolateral orbital area and may be involved in emotional and aversive aspects of nociceptive information processing, whereas the ventral Sm pathway seems to co-activate distant orbitofrontal cortical areas, and may link their functions under certain circumstances.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Dorsal and ventral parts of thalamic nucleus submedius project to different areas of rat orbitofrontal cortex: A single neuron‐tracing study using virus vectors

Kuramoto

Iwai

Yamanaka

et al. 2017

J of Comparative Neurology

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“…Rose and Woolsey originally proposed the terminal fields of projections from the mediodorsal nucleus of the thalamus as a criterion for defining the prefrontal cortex [82]. Axons from the lateral division of MD thalamus project to M2 [19,83,84]. On the whole, MD thalamic projections can be found in M2 as well as orbital, prelimbic, infralimbic, anterior cingulate, and agranular insular regions, but they are absent in primary motor and sensory cortices in mice [85].…”

Section: Afferent Connections From Diverse Cortical and Thalamic Sourcesmentioning

confidence: 99%

Secondary Motor Cortex: Where ‘Sensory’ Meets ‘Motor’ in the Rodent Frontal Cortex

Barthas

Kwan

2017

Trends in Neurosciences

234

198

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In rodents, the medial aspect of the secondary motor cortex (M2) is known by other names including medial agranular cortex, precentral cortex, and frontal orienting field. As a subdivision of the medial prefrontal cortex, M2 can be defined by a distinct set of afferent and efferent connections, microstimulation responses, and lesion outcomes. However, the behavioral role of M2 remains mysterious. Here, we focus on evidence from rodent studies, highlighting recent findings of early and context-dependent choice-related activity in M2 during voluntary behavior. Based on the current understanding, we suggest that a major function for M2 is to flexibly map such antecedent signals as sensory cues to motor actions, thereby enabling adaptive choice behavior.

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“…Anatomically, thalamic output to the cortex is quite variable, with only a minority of thalamic circuits exhibiting a topographic and spatially restricted innervation of a single cortical target [30,31]. Additionally, many thalamic circuits receive convergent inputs from a single or multiple cortical regions that do not appear to be compatible with the idea of topographic relay [32].…”

Section: Thalamic Regulation Of Functional Cortical Connectivitymentioning

confidence: 99%

Thalamic control of functional cortical connectivity

Nakajima

Halassa

2017

Current Opinion in Neurobiology

165

104

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The thalamus is an evolutionarily conserved structure with extensive reciprocal connections to cortical regions. While its role in transmitting sensory signals is well-studied, its broader engagement in cognition is unclear. In this review, we discuss evidence that the thalamus regulates functional connectivity within and between cortical regions, determining how a cognitive process is implemented across distributed cortical microcircuits. Within this framework, thalamic circuits do not necessarily determine the categorical content of a cognitive process (e.g. sensory details in feature-based attention), but rather provide a route by which task-relevant cortical representations are sustained and coordinated. Additionally, thalamic control of cortical connectivity bridges general arousal to the specific processing of categorical content, providing an intermediate level of cognitive and circuit description that will facilitate mapping neural computations onto thought and behavior.

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Individual mediodorsal thalamic neurons project to multiple areas of the rat prefrontal cortex: A single neuron‐tracing study using virus vectors

Cited by 111 publications

References 59 publications

Dorsal and ventral parts of thalamic nucleus submedius project to different areas of rat orbitofrontal cortex: A single neuron‐tracing study using virus vectors

Dorsal and ventral parts of thalamic nucleus submedius project to different areas of rat orbitofrontal cortex: A single neuron‐tracing study using virus vectors

Secondary Motor Cortex: Where ‘Sensory’ Meets ‘Motor’ in the Rodent Frontal Cortex

Thalamic control of functional cortical connectivity

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