An Architectonic Study of the Neocortex of the Short-Tailed Opossum &lt;i&gt;(Monodelphis domestica)&lt;/i&gt;

Wong, Peiyan; Kaas, Jon H.

doi:10.1159/000225381

Cited by 42 publications

(56 citation statements)

References 211 publications

(205 reference statements)

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“…Marsupialia consists of nearly 350 extant species divided into 4 Australasian and 3 South American orders [Nilsson et al, 2010;Gallus et al, 2015;May-Collado et al, 2015]. While the neuroanatomy, connectivity, neocortical development, and physiology of the brain in some representative marsupial species have been studied [Saunders et al, 1989;Rosa et al, 1999;Ashwell et al, 2008;Wong and Kaas, 2009;Watson et al, 2012], little is known about the cellular composition of marsupial brains and how it compares with other clades, besides a report of a low neuronal density in the neocortex of a single species, the opossum (Didelphis virginiana) , in comparison to other mammals [Haug, 1987]. Recently, two more detailed studies were conducted on the cellular composition of another species, the gray short-tailed opossum Monodelphis domestica, during development [Seelke et al, 2013] and across the primary sensory fields of its neocortex [Seelke et al, 2014].…”

Section: Introductionmentioning

confidence: 99%

Cellular Scaling Rules for the Brains of Marsupials: Not as “Primitive” as Expected

Santos

Porfírio²,

Cunha³

et al. 2017

Brain Behav Evol

1,837

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In the effort to understand the evolution of mammalian brains, we have found that common relationships between brain structure mass and numbers of nonneuronal (glial and vascular) cells apply across eutherian mammals, but brain structure mass scales differently with numbers of neurons across structures and across primate and nonprimate clades. This suggests that the ancestral scaling rules for mammalian brains are those shared by extant nonprimate eutherians - but do these scaling relationships apply to marsupials, a sister group to eutherians that diverged early in mammalian evolution? Here we examine the cellular composition of the brains of 10 species of marsupials. We show that brain structure mass scales with numbers of nonneuronal cells, and numbers of cerebellar neurons scale with numbers of cerebral cortical neurons, comparable to what we have found in eutherians. These shared scaling relationships are therefore indicative of mechanisms that have been conserved since the first therians. In contrast, while marsupials share with nonprimate eutherians the scaling of cerebral cortex mass with number of neurons, their cerebella have more neurons than nonprimate eutherian cerebella of a similar mass, and their rest of brain has fewer neurons than eutherian structures of a similar mass. Moreover, Australasian marsupials exhibit ratios of neurons in the cerebral cortex and cerebellum over the rest of the brain, comparable to artiodactyls and primates. Our results suggest that Australasian marsupials have diverged from the ancestral Theria neuronal scaling rules, and support the suggestion that the scaling of average neuronal cell size with increasing numbers of neurons varies in evolution independently of the allocation of neurons across structures.

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Section: Introductionmentioning

confidence: 99%

Cellular Scaling Rules for the Brains of Marsupials: Not as “Primitive” as Expected

Santos

Porfírio²,

Cunha³

et al. 2017

Brain Behav Evol

1,837

View full text Add to dashboard Cite

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“…This difference in anatomical projections is obvious following the effects of area 17 lesions, which in primates causes a condition that approximates complete blindness but in other mammals is much less severe (Killackey et al, 1971, 1972; Funk and Rosa, 1998). Also, the subdivisions within the input layers, and presumed segregation of innervation to sublayers containing different cell classes, varies in other mammals from prominent (Freund et al, 1985; Wong and Kaas, 2008) to weak or absent (Wong and Kaas, 2009). It is notable that in at least one species, the tree shrew, the geniculostriate terminations in layer 4 convey not transient and sustained responses, but rather “on” and “off” responses, which are similarly segregated in the retina and in the LGN (Conley et al, 1984; Van Hooser et al, 2013).…”

Section: The Primate Brain: a Commitment To Visionmentioning

confidence: 99%

The marmoset monkey as a model for visual neuroscience

Mitchell

Leopold

2015

Neuroscience Research

215

182

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The common marmoset (Callithrix jacchus) has been valuable as a primate model in biomedical research. Interest in this species has grown recently, in part due to the successful demonstration of transgenic marmosets. Here we examine the prospects of the marmoset model for visual neuroscience research, adopting a comparative framework to place the marmoset within a broader evolutionary context. The marmoset’s small brain bears most of the organizational features of other primates, and its smooth surface offers practical advantages over the macaque for areal mapping, laminar electrode penetration, and two-photon and optical imaging. Behaviorally, marmosets are more limited at performing regimented psychophysical tasks, but do readily accept the head restraint that is necessary for accurate eye tracking and neurophysiology, and can perform simple discriminations. Their natural gaze behavior closely resembles that of other primates, with a tendency to focus on objects of social interest including faces. Their immaturity at birth and routine twinning also makes them ideal for the study of postnatal visual development. These experimental factors, together with the theoretical advantages inherent in comparing anatomy, physiology, and behavior across related species, make the marmoset an excellent model for visual neuroscience.

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“…Fossil evidence suggests the presence of opossum-like animals in the early Cretaceous period (greater than 100 mya) [36]; hence M. domestica may have many of the traits possessed by a common ancestor of both modern marsupial and placental mammals. In particular, the opossum brain has a smaller number of cortical areas than most mammals [37], lacks a distinct motor cortex, and has relatively few corticospinal neurons [38]. Thus, it may be reasonably representative of an ancestral mammalian brain (motor cortex and the corticospinal tract are both new in mammals).…”

Section: Introductionmentioning

confidence: 99%

Active vibrissal sensing in rodents and marsupials

Mitchinson

Grant

Arkley

et al. 2011

Phil. Trans. R. Soc. B

112

146

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In rats, the long facial whiskers (mystacial macrovibrissae) are repetitively and rapidly swept back and forth during exploration in a behaviour known as 'whisking'. In this paper, we summarize previous evidence from rats, and present new data for rat, mouse and the marsupial grey short-tailed opossum (Monodelphis domestica) showing that whisking in all three species is actively controlled both with respect to movement of the animal's body and relative to environmental structure. Using automatic whisker tracking, and Fourier analysis, we first show that the whisking motion of the mystacial vibrissae, in the horizontal plane, can be approximated as a blend of two sinusoids at the fundamental frequency (mean 8.5, 11.3 and 7.3 Hz in rat, mouse and opossum, respectively) and its second harmonic. The oscillation at the second harmonic is particularly strong in mouse (around 22 Hz) consistent with previous reports of fast whisking in that species. In all three species, we found evidence of asymmetric whisking during head turning and following unilateral object contacts consistent with active control of whisker movement. We propose that the presence of active vibrissal touch in both rodents and marsupials suggests that this behavioural capacity emerged at an early stage in the evolution of therian mammals.

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An Architectonic Study of the Neocortex of the Short-Tailed Opossum <i>(Monodelphis domestica)</i>

Cited by 42 publications

References 211 publications

Cellular Scaling Rules for the Brains of Marsupials: Not as “Primitive” as Expected

Cellular Scaling Rules for the Brains of Marsupials: Not as “Primitive” as Expected

The marmoset monkey as a model for visual neuroscience

Active vibrissal sensing in rodents and marsupials

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