Reduction in cell size during development of the spinal cord

Chen, Aileen B.; Ekman, Jonathan M.; Heathcote, R. David

doi:10.1002/(sici)1096-9861(19990712)409:4<592::aid-cne6>3.0.co;2-p

Cited by 9 publications

(11 citation statements)

References 59 publications

(26 reference statements)

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“…Our results taken together with previous studies (Lamborghini, 1980;Thors et al, 1982a,b;van Mier, 1986;Hartenstein, 1989Hartenstein, , 1993Chen et al, 1999) allow us to define three phases of Xenopus spinal cord development (Fig. 1).…”

Section: Discussion Neurogenesis In the Xenopus Spinal Cord Proceeds supporting

confidence: 78%

“…The two layers of the neuroectoderm have interdigitated and now form an unilayered and pseudostratified epithelium (Schroeder, 1970;Davidson and Keller, 1999), in which the mitotic nuclei are confined to the ventricular surface (Hartenstein, 1989). There is no increase in the diameter of the spinal cord throughout this period (Thors et al, 1982a;Chen et al, 1999), because increase in cell number due to low-level proliferation (Hartenstein, 1989;Chen et al, 1999) is largely compensated for by decrease in cell size (Chen et al, 1999). From stage 35/36 onward, rates of cell proliferation further decline (Chen et al, 1999) reflected in reduced levels of XNeuroD and XMyT1 expression from stage 37/38 onward.…”

Section: Discussion Neurogenesis In the Xenopus Spinal Cord Proceeds mentioning

confidence: 99%

“…1). Neurogenesis continues at later embryonic stages, when mainly interneurons are born (Hartenstein, 1989;Chen et al, 1999;Binor and Heathcote, 2001). After a quiescent period, the majority of secondary neurons, such as the motor neurons of the lateral motor columns, the sensory dorsal root ganglion cells, as well as many spinal interneurons, are then born during a larval period of neurogenesis (Fig.…”

Section: Introductionmentioning

confidence: 99%

“…The hatched black line provides a rough sketch of interneuron generation. The time course of interneuron generation rates before stage 48 is unknown (question marks), but average rates between stage 22 and stage 37/38 can be estimated from interneuron counts provided by Roberts (1989), rates between stage 37/38 and 46 must be lower (Chen et al, 1999), whereas at later stages, rates and numbers relative to motor neurons can be estimated from Thors et al (1982b). No reliable information is available on neuron generation rates at stages later than stage 53 (LMC, DRG) or 56 (interneurons).…”

Section: Introductionmentioning

confidence: 99%

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Thyroid hormone promotes neurogenesis in the Xenopus spinal cord

Schlosser

Koyano-Nakagawa

Kintner

2002

Developmental Dynamics

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Three phases of neurogenesis can be recognized during Xenopus spinal cord development. An early peak during gastrulation/ neurulation is followed by a phase of low level neurogenesis throughout the remaining embryonic stages and a later peak at early larval stages. We show here that several genes known to be essential for early neurogenesis (X-NGNR-1, XNeuroD, XMyT1, X-Delta-1) are also expressed during later phases of neurogenesis in the spinal cord, suggesting that they are involved in regulating spinal neurogenesis at later stages. However, additional neuronal determination genes may be important during larval stages, because X-NGNR-1 shows only scant expression in the spinal cord during larval stages. Thyroid hormone treatment of early larvae promotes neurogenesis in the spinal cord, where thyroid hormone receptor xTR␣ is expressed from early larval stages onward and results in precocious up-regulation of XNeuroD, XMyT1, and N-Tubulin expression. Similarly, thyroid hormone treatments of Xenopus embryos, which were coinjected with xTR␣ and the retinoid X receptor xRXR␣, repeatedly resulted in increased numbers of neurons, whereas unliganded receptors repressed neurogenesis. Our findings show that thyroid hormones are sufficient to up-regulate neurogenesis in the Xenopus spinal cord.

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Section: Discussion Neurogenesis In the Xenopus Spinal Cord Proceeds supporting

confidence: 78%

Section: Discussion Neurogenesis In the Xenopus Spinal Cord Proceeds mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Thyroid hormone promotes neurogenesis in the Xenopus spinal cord

Schlosser

Koyano-Nakagawa

Kintner

2002

Developmental Dynamics

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“…2B). These results support the hy- Chen et al, 1999). Most of these cells are primary dopaminergic neurons (Binor and Heathcote, 2001).…”

Section: Elimination Of the Notochordsupporting

confidence: 84%

Establishment of a ventral cell fate in the spinal cord

Moghadam

Chen

Heathcote

2003

Developmental Dynamics

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The neural plate is induced during gastrulation when the organizer affects the ectoderm around it. Recent experiments show that axial mesoderm can stimulate formation of specific ventral cell types in the spinal cord, including floor plate, motor neurons, and several types of interneurons. We have eliminated or disrupted axial mesoderm by using a variety of methods to show that ventral columns of intermittent dopaminergic neurons in the frog Xenopus also appear to be induced by axial mesoderm. Inversion of the dorsal-ventral neural axis by splitting the presumptive neural plate in vivo, produced two spinal cords with ectopic dopaminergic neurons. The location and number of neurons suggest that even a brief association with axial mesoderm can specify the identity of the first or primary dopaminergic neurons and that notochord retains the ability to induce cells to become secondary dopaminergic neurons. Developmental Dynamics 227:552-562, 2003.

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Development of GABA‐immunoreactive neuron patterning in the spinal cord

Binor

Heathcote

2001

J of Comparative Neurology

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In the frog Xenopus laevis, gamma-aminobutyric acid (GABA)-immunoreactive spinal cord neurons (Kolmer-Agduhr cells) formed a dispersed pattern within two columns on either side of the midline. The cellular pattern became established during embryonic and larval development. The GABA-immunoreactive cells are cerebrospinal fluid (CSF)-contacting neurons that began to appear by 1.2 days (st 26) of development. This stage occurred shortly after neural tube closure (0.9 days, st 21) and followed the appearance of ultrastructural characteristics of CSF-contacting neurons. The pattern of GABA-immunoreactive cells emerged during embryogenesis, as their density increased. Each longitudinal column was heterogeneous, containing cells with and without GABA immunoreactivity. Spatial analysis at several embryonic and larval stages showed that the cells in each column formed a nonrandom, dispersed pattern even at early stages of differentiation. This one-dimensional pattern resembled that of dopamine-immunoreactive neurons, which are also located in the ventral spinal cord. The patterning of both cell types followed a different time course, but the ultimate spacing of the neurons remained comparable. These results suggested that the mechanism patterning the two cell types within the same region was similar but not identical and may involve related molecular mechanisms.

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Reduction in cell size during development of the spinal cord

Cited by 9 publications

References 59 publications

Thyroid hormone promotes neurogenesis in the Xenopus spinal cord

Thyroid hormone promotes neurogenesis in the Xenopus spinal cord

Establishment of a ventral cell fate in the spinal cord

Development of GABA‐immunoreactive neuron patterning in the spinal cord

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