Your search keyword '"Sox21"' showing total 6 results

1. Craniofacial Development Is Fine-Tuned by Sox2.

Author

Mandalos, Nikolaos Panagiotis, Dimou, Aikaterini, Gavala, Maria Angeliki, Lambraki, Efstathia, and Remboutsika, Eumorphia

Subjects

*NEURAL stem cells, *NEURAL crest, *ONTOGENY, *EMBRYONIC stem cells, *PLURIPOTENT stem cells, *PROGENITOR cells

Abstract

The precise control of neural crest stem cell delamination, migration and differentiation ensures proper craniofacial and head development. Sox2 shapes the ontogeny of the cranial neural crest to ensure precision of the cell flow in the developing head. Here, we review how Sox2 orchestrates signals that control these complex developmental processes. [ABSTRACT FROM AUTHOR]

Published

2023

2. Sequential Role of SOXB2 Factors in GABAergic Neuron Specification of the Dorsal Midbrain

Author

Neoklis Makrides, Elena Panayiotou, Pavlos Fanis, Christos Karaiskos, George Lapathitis, and Stavros Malas

Subjects

SOX21, SOX14, SOXB2, midbrain, development, GABAergic, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Studies proposed a model for embryonic neurogenesis where the expression levels of the SOXB2 and SOXB1 factors regulate the differentiation status of the neural stem cells. However, the precise role of the SOXB2 genes remains controversial. Therefore, this study aims to investigate the effects of individual deletions of the SOX21 and SOX14 genes during the development of the dorsal midbrain. We show that SOX21 and SOX14 function distinctly during the commitment of the GABAergic lineage. More explicitly, deletion of SOX21 reduced the expression of the GABAergic precursor marker GATA3 and BHLHB5 while the expression of GAD6, which marks GABAergic terminal differentiation, was not affected. In contrast deletion of SOX14 alone was sufficient to inhibit terminal differentiation of the dorsal midbrain GABAergic neurons. Furthermore, we demonstrate through gain-of-function experiments, that despite the homology of SOX21 and SOX14, they have unique gene targets and cannot compensate for the loss of each other. Taken together, these data do not support a pan-neurogenic function for SOXB2 genes in the dorsal midbrain, but instead they influence, sequentially, the specification of GABAergic neurons.

Published

2018

3. Sequential Role of SOXB2 Factors in GABAergic Neuron Specification of the Dorsal Midbrain.

Author

Makrides, Neoklis, Panayiotou, Elena, Fanis, Pavlos, Karaiskos, Christos, Lapathitis, George, and Malas, Stavros

Subjects

MESENCEPHALON, DEVELOPMENTAL neurobiology, GABAERGIC neurons

Abstract

Studies proposed a model for embryonic neurogenesis where the expression levels of the SOXB2 and SOXB1 factors regulate the differentiation status of the neural stem cells. However, the precise role of the SOXB2 genes remains controversial. Therefore, this study aims to investigate the effects of individual deletions of the SOX21 and SOX14 genes during the development of the dorsal midbrain. We show that SOX21 and SOX14 function distinctly during the commitment of the GABAergic lineage. More explicitly, deletion of SOX21 reduced the expression of the GABAergic precursor marker GATA3 and BHLHB5 while the expression of GAD6, which marks GABAergic terminal differentiation, was not affected. In contrast deletion of SOX14 alone was sufficient to inhibit terminal differentiation of the dorsal midbrain GABAergic neurons. Furthermore, we demonstrate through gain-of-function experiments, that despite the homology of SOX21 and SOX14, they have unique gene targets and cannot compensate for the loss of each other. Taken together, these data do not support a pan-neurogenic function for SOXB2 genes in the dorsal midbrain, but instead they influence, sequentially, the specification of GABAergic neurons. [ABSTRACT FROM AUTHOR]

Published

2018

4. Sox2: To crest or not to crest?

Author

Mandalos, Nikolaos Panagiotis and Remboutsika, Eumorphia

Subjects

*HEAD growth, *SOX transcription factors, *PROGENITOR cells, *CELL transformation, *NEURAL crest

Abstract

Precise control of neural progenitor transformation into neural crest stem cells ensures proper craniofacial and head development. In the neural progenitor pool, SoxB factors play an essential role as cell fate determinants of neural development, whereas during neural crest stem cell formation, Sox2 plays a predominant role as a guardian of the developmental clock that ensures precision of cell flow in the developing head. [ABSTRACT FROM AUTHOR]

Published

2017

5. Expression and Function of Sox21 During Mouse Cochlea Development.

Author

Hosoya, Makoto, Fujioka, Masato, Matsuda, Satoru, Ohba, Hiroyuki, Shibata, Shinsuke, Nakagawa, Fumiko, Watabe, Takahisa, Wakabayashi, Ken-ichiro, Saga, Yumiko, Ogawa, Kaoru, Okano, Hirotaka, and Okano, Hideyuki

Subjects

*GENE expression, *COCHLEA, *LABORATORY mice, *HAIR cells, *INNER ear, *TRANSCRIPTION factors, *EPITHELIUM, *MORPHOGENESIS

Abstract

The development of the inner ear is an orchestrated process of morphogenesis with spatiotemporally controlled generations of individual cell types. Recent studies have revealed that the Sox gene family, a family of evolutionarily conserved HMG-type transcriptional factors, is differentially expressed in each cell type of the mammalian inner ear and plays critical roles in cell-fate determination during development. In this study, we examined the expression pattern of Sox21 in the developing and adult murine cochlea. Sox21 was expressed throughout the sensory epithelium in the early otocyst stage but became restricted to supporting cells during adulthood. Interestingly, the expression in adults was restricted to the inner phalangeal, inner border, and Deiters' cells: all of these cells are in direct contact with hair cells. Evaluations of the auditory brainstem-response revealed that Sox21 mice suffered mild hearing impairments, with an increase in hair cells that miss their appropriate planar cell polarity. Taken together with the previously reported critical roles of SoxB1 families in the morphogenesis of inner ear sensory and neuronal cells, our results suggest that Sox21, a counteracting partner of the SoxB1 family, controls fine-tuned cell fate decisions. Also, the characteristic expression pattern may be useful for labelling a particular subset of supporting cells. [ABSTRACT FROM AUTHOR]

Published

2011

6. Sox21 is a repressor of neuronal differentiation and is antagonized by YB-1

Author

Ohba, Hiroyuki, Chiyoda, Tatsuyuki, Endo, Emmy, Yano, Masato, Hayakawa, Yoshika, Sakaguchi, Masanori, Darnell, Robert B., Okano, Hirotaka J., and Okano, Hideyuki

Subjects

*TRANSCRIPTION factors, *CELL differentiation, *GENE expression, *NERVOUS system

Abstract

Sox21, a high-mobility group box transcription factor, is expressed throughout the immature neural stem/progenitor population in ventricular zone but not in the cortical plate in embryonic mouse brain and its expression is restricted to the subventricular zone in the adult brain. In undifferentiated PC12 cells, endogenous Sox21 expression is detected but its expression ceases during the nerve growth factor (NGF)-induced neuronal differentiation. Overexpression of Sox21 results in a substantial repression of NGF-induced neurite outgrowth in PC12 cells. Further, we biochemically identified a Sox21-associating protein, Y-box binding protein 1 which not only binds to Sox21 but also partially restores NGF-induced neurite outgrowth of PC12 cells inhibited by Sox21. These results suggest that Sox21 is a repressor of neuronal differentiation in the developing nervous system. [Copyright &y& Elsevier]

Published

2004