Cell Types in the Mustached Bat Auditory Cortex

Fitzpatrick, Douglas C.; Henson, O. W.

doi:10.1159/000113626

Cited by 30 publications

(31 citation statements)

References 17 publications

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“…Spiny cells that are not stellate or pyramidal are occasionally encountered here but, as a group, do not display consistent anatomical or physiological features that might allow them to function as auditory cortical versions of the visual spiny stellates. Our data, combined with anatomical evidence from previous Golgi studies in several species, indicate that the spiny stellate is not the predominant or even a major cell type in any auditory thalamocortical recipient zone studied (McMullen and Glaser, 1982;Meyer and Ferres-Torres, 1984;Winer, 1984;Fitzpatrick and Henson, 1994).…”

Section: Discussionsupporting

confidence: 53%

“…Rose's observation may have foreshadowed observations of fundamental differences between layer 4 in auditory and other sensory cortices. Golgi studies in rabbit (McMullen and Glaser, 1982), cat (Winer, 1984), mustached bat (Fitzpatrick and Henson, 1994), and human (Meyer and Ferres-Torres, 1984;Meyer et al, 1989) showed that spiny stellates are rare in layer 4. In contrast to the symmetric dendritic trees of visual and somatosensory spiny stellates that are confined to layer 4, a great variety occurs in the dendritic arborization patterns of these infrequently encountered cells purported to be spiny stellate homologues.…”

mentioning

confidence: 99%

“…If spiny stellate cells are not the primary excitatory cell type, what is? Several reports (McMullen and Glaser, 1982;Meyer et al, 1989;Fitzpatrick and Henson, 1994) indicate that pyramidal cells populate layer 4 in several species, although they are reported to be absent in cat primary auditory cortex (Winer, 1984).…”

mentioning

confidence: 99%

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Fundamental differences between the thalamocortical recipient layers of the cat auditory and visual cortices

Smith

Populin

2001

J of Comparative Neurology

118

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In visual and somatosensory cortices of several species, spiny stellate cells in layer 4 are the first elements in signal processing where thalamic information is integrated and emergent receptive field properties are generated and sent on to more superficial cortical layers. In vivo and in vitro experiments have provided important information about how the anatomy and physiology of these cells and this layer fit into the functional cortical circuitry. No such data exist for the auditory cortex but are requisite if we are to understand whether ideas about information processing in one sensory cortical area can be generalized to another. Accordingly, we used in vitro slices from which to record and labeled cells in the middle layers of the cat auditory and visual cortices to compare basic anatomical and physiological features of cells recovered in similar layers using the same methods. Our results demonstrate a striking difference in a basic characteristic of two primary sensory cortical areas. In the visual cortex, spiny stellate cells predominate, receive short-latency synaptic inputs, and project to supergranular layers. No such spiny stellate population is encountered in the middle layers of the auditory cortex. Spiny cells that are not stellate or pyramidal are occasionally encountered but, as a group, do not display consistent anatomical or physiological features that might allow them to function as auditory cortical versions of the visual spiny stellates. Rather, pyramidal cells in the lower half of layer 3 and layer 4 appear to have assumed this role.

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Section: Discussionsupporting

confidence: 53%

mentioning

confidence: 99%

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Fundamental differences between the thalamocortical recipient layers of the cat auditory and visual cortices

Smith

Populin

2001

J of Comparative Neurology

118

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“…This insectivore (suborder: Tenrecomorpha;Eisenberg 1981;Piccinini et al 1991;McPhee and Novacek 1993), was shown to have one of the lowest neocorticalization indices (Stephan et al 1991). In contrast to monotremes, marsupials and most other placental mammals, Echinops telfairi does not exhibit any granularization indicative of the presence of a lamina IV throughout its entire neocortex (Rehkämper 1981;Garey et al 1985;Rowe 1990;Glezer et al 1993;Fitzpatrick and Henson 1994;Krause and Saunders 1994;Nieuwenhuys 1994;Harman et al 1995). In this species, furthermore, some non-neocortical regions, such as the entorhinal and prepiriform cortices and the hippocampus, are characterized by a trilaminar architecture, with one main cellular layer situated between two layers consisting predominantly of neuropil.…”

Section: Introductionmentioning

confidence: 89%

On the presence of dendrite bundles in the cerebral cortex of the Madagascan lesser hedgehog tenrec and the red-eared pond turtle

Schmolke¹,

Künzle

1997

Anatomy and Embryology

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In mammals with a well-differentiated neocortex apical dendrites of pyramidal cells form vertical bundles. Little is known about the presence of dendrite bundles in animals with a poorly differentiated cortex. In this paper the presence of dendrite bundles has been investigated in the lesser hedgehog tenrec, Echinops telfairi, a basal insectivore with a very low degree of neocorticalization. In a further step the arrangement of dendrites has been analyzed in the cerebral cortex of the red-eared pond turtle, Pseudemys scripta elegans. Among non-mammalian vertebrates, reptiles have a cerebral cortex that is relatively most comparable with the mammalian one, and the cerebral cortex of turtles shows more structural and functional similarities with the cortex in mammals than those of other reptiles. In the hedgehog tenrec, bundles of apical dendrites are found in all neo-cortical areas, the cingulate and retrosplenial cortices. The shape and arrangement of dendrite bundles are primarily determined by apical dendrites of lamina V pyramids. Apical dendrites originating in laminae III/IV or VI join these bundles, and do not give rise to separate sets of bundles in the supra- and infragranular layers as in other mammals. Center to center distances between bundles determined in the neocortical areas A(2-4) range from 7 to 76 microm, with an average of 32 microm. Area-specific differences are found concerning the length of bundles as well as the number, caliber, branching pattern and packing density of dendrites sharing an individual bundle. In the three-layered entorhinal cortex and the hippocampus dendrite bundles are not observed. In the turtle, no vertical bundles of dendrites are seen either in the medial, dorsomedial or medial part of the dorsal cortex. Only in the lateral part of the dorsal cortex are isolated bundles of apical dendrites originating from groups of perikarya situated below the main level of lamina II detected. Our findings suggest that the presence of dendrite bundles is closely related with the multilayered nature of the mammalian neocortex.

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“…In the literature, there appears to be little agreement on whether these bifurcating apical branches are characteristic of bitufted (Bartesaghi et al 2003), multiapical (Ferrer et al 1986a, b), or even extraverted pyramidal neurons (Fitzpatrick and Henson 1994). Although resembling layer II extraverted pyramidal neurons in several other species (hedgehog, bat, and opossum: Sanides and Sanides 1972;dolphin: Glezer and Morgane 1990;quokka: Tyler et al 1998; humpback whale: Hof and Van der Gucht 2007; giant elephant shrew, giant and lesser anteater: Sherwood et al 2009), elephant superficial pyramidal neurons did not meet the strict definition of extraversion, whereby apical dendritic extent exceeds that of basilar dendrites (Sanides and Sanides 1972).…”

Section: Elephant Superficial Pyramidal Neurons and Human Supragranulmentioning

confidence: 99%

Neuronal morphology in the African elephant (Loxodonta africana) neocortex

et al. 2010

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Virtually nothing is known about the morphology of cortical neurons in the elephant. To this end, the current study provides the first documentation of neuronal morphology in frontal and occipital regions of the African elephant (Loxodonta africana). Cortical tissue from the perfusion-fixed brains of two free-ranging African elephants was stained with a modified Golgi technique. Neurons of different types (N=75), with a focus on superficial (i.e., layers II-III) pyramidal neurons, were quantified on a computer-assisted microscopy system using Neurolucida software. Qualitatively, elephant neocortex exhibited large, complex spiny neurons, many of which differed in morphology/orientation from typical primate and rodent pyramidal neurons. Elephant cortex exhibited a V-shaped arrangement of bifurcating apical dendritic bundles. Quantitatively, the dendrites of superficial pyramidal neurons in elephant frontal cortex were more complex than in occipital cortex. In comparison to human supragranular pyramidal neurons, elephant superficial pyramidal neurons exhibited similar overall basilar dendritic length, but the dendritic segments tended to be longer in the elephant with less intricate branching. Finally, elephant aspiny interneurons appeared to be morphologically consistent with other eutherian mammals. The current results thus elaborate on the evolutionary roots of Afrotherian brain organization and highlight unique aspects of neural architecture in elephants.

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Cell Types in the Mustached Bat Auditory Cortex

Cited by 30 publications

References 17 publications

Fundamental differences between the thalamocortical recipient layers of the cat auditory and visual cortices

Fundamental differences between the thalamocortical recipient layers of the cat auditory and visual cortices

On the presence of dendrite bundles in the cerebral cortex of the Madagascan lesser hedgehog tenrec and the red-eared pond turtle

Neuronal morphology in the African elephant (Loxodonta africana) neocortex

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