Molecular anatomy of the alligator dorsal telencephalon

Briscoe, Steven D.; Ragsdale, Clifton W.

doi:10.1002/cne.24427

Cited by 26 publications

(39 citation statements)

References 102 publications

(197 reference statements)

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“…The hypothesis of cellular homology also prescribes that the same cell types were anatomically "rearranged" into distinct laminae in the mammalian neocortex and into distinct components of the sauropsid DVR, by coopting different developmental mechanisms (Briscoe & Ragsdale, 2018a. We strongly agree with this assertion in terms of the mechanisms: In the neocortex, a single neural progenitor from the dorsal pallium sequentially generates the components of the microcircuit (Telley et al, 2019).…”

Section: Revived: a Conserved Pallial Microcircuitsupporting

confidence: 56%

“…A renewed version of the DVR-neocortex homology hypothesis has been supported by recent findings revealing that neurons in distinct laminae of the mammalian neocortex display similar microcircuitry and molecular markers as those observed in different components of the DVR and in the dorsal cortex/Wulst of sauropsids (Ahumada-Galleguillos, Fernández, Marin, Letelier, & Mpodozis, 2015;Briscoe & Ragsdale, 2018aDugas-Ford, Rowell, & Ragsdale, 2012;Faunes, Botelho, Ahumada Galleguillos, & Mpodozis, 2015;Fredes, Tapia, Letelier, Marín, & Mpodozis, 2010). This interpretation asserts that there are homologous neuronal populations in both structures so that the same canonical input-output processing microcircuit was present in the amniote last-common ancestor and was allocated to the mammalian neocortex and to the sauropsid DVR and dorsal cortex/Wulst (Briscoe & Ragsdale, 2018b).…”

Section: Revived: a Conserved Pallial Microcircuitmentioning

confidence: 94%

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Morphological evolution of the vertebrate forebrain: From mechanical to cellular processes

Aboitiz

Montiel

2019

Evolution and Development

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Although the cerebral hemispheres are among the defining characters of vertebrates, each vertebrate class is characterized by a different anatomical organization of this structure, which has become highly problematic for comparative neurobiology. In this article, we discuss some mechanisms involved in the generation of this morphological divergence, based on simple spatial constraints for neurogenesis and mechanical forces generated by increasing neuronal numbers during development, and the different cellular strategies used by each group to overcome these limitations. We expect this view to contribute to unify the diverging vertebrate brain morphologies into general, simple mechanisms that help to establish homologies across groups. K E Y W O R D Sbasal progenitors, dorsal ventricular ridge, eversion, ganglionic eminences, neocortex, subventricular zone, telencephalon, ventricular zone

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Section: Revived: a Conserved Pallial Microcircuitsupporting

confidence: 56%

Section: Revived: a Conserved Pallial Microcircuitmentioning

confidence: 94%

Morphological evolution of the vertebrate forebrain: From mechanical to cellular processes

Aboitiz

Montiel

2019

Evolution and Development

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“…Six transcription factors characterize the avian mesopallium (17), which, as defined by Jarvis et al (11), includes a dorsal division associated with the Wulst and a ventral division in the DVR. Gene expression experiments in alligators revealed a similar bipartite organization, with mesopalliumlike cells in the dorsal cortex and a mesopallium in the DVR (17,18). Cell populations in turtle and lizard cortices also express several of the mesopallium transcription factors, indicating that mesopallium-like cell types are shared across sauropsids (16).…”

Section: Intratelencephalic Neurons and The Evolution Of Higher Cognimentioning

confidence: 91%

“…For example, the paralogous genes RORA and RORB, both of which regulate the differentiation of neocortical input neurons (23,24), are expressed by pallial input cells of birds and reptiles (10,11,16,18). These two transcription factors, together with SATB1 (16,18), may participate in a conserved gene regulatory network for the identity of pallial input cells, including their connections and physiological properties (Fig. 2, ancestral input cell).…”

Section: Specification and Evolution Of Pallial Neuronal Cell Typesmentioning

confidence: 99%

Homology, neocortex, and the evolution of developmental mechanisms

Briscoe

Ragsdale

2018

Science

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The six-layered neocortex of the mammalian pallium has no clear homolog in birds or non-avian reptiles. Recent research indicates that although these extant amniotes possess a variety of divergent and nonhomologous pallial structures, they share a conserved set of neuronal cell types and circuitries. These findings suggest a principle of brain evolution: that natural selection preferentially preserves the integrity of information-processing pathways, whereas other levels of biological organization, such as the three-dimensional architectures of neuronal assemblies, are less constrained. We review the similarities of pallial neuronal cell types in amniotes, delineate candidate gene regulatory networks for their cellular identities, and propose a model of developmental evolution for the divergence of amniote pallial structures.

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“…Birds and nonavian reptiles do not possess a neocortex, but their telencephala do contain several classes of excitatory neuronal cell types that are remarkably similar to mammalian neocortical neurons in terms of their connectivity patterns [Briscoe et al, 2018;Briscoe and Ragsdale, 2018b]. Rather than being stacked into a 6-layered cortical structure, these avian and reptilian neuronal cell types are generally organized into clustered nuclei within a structure called the dorsal ventricular ridge.…”

Section: The Hierarchical Organization Of Homologies: Neural Circuit mentioning

confidence: 99%