Your search keyword '"Cheah, Kathryn S. E."' showing total 11 results

1. Hypomorphic and dominant-negative impact of truncated SOX9 dysregulates Hedgehog-Wnt signaling, causing campomelia.

Author

Au, Tiffany Y. K., Yip, Raymond K. H., Wynn, Sarah L., Tan, Tiong Y., Fu, Alex, Yu Hong Geng, Szeto, Irene Y. Y., Niu, Ben, Yip, Kevin Y., Cheung, Martin C. H., Lovell-Badge, Robin, and Cheah, Kathryn S. E.

Subjects

SOX transcription factors, WNT signal transduction, TRANSCRIPTION factors, EXTRACELLULAR matrix, CHONDROGENESIS

Abstract

Haploinsufficiency for SOX9, the master chondrogenesis transcription factor, can underlie campomelic dysplasia (CD), an autosomal dominant skeletal malformation syndrome, because heterozygous Sox9 null mice recapitulate the bent limb (campomelia) and some other phenotypes associated with CD. However, in vitro cell assays suggest haploinsufficiency may not apply for certain mutations, notably those that truncate the protein, but in these cases in vivo evidence is lacking and underlying mechanisms are unknown. Here, using conditional mouse mutants, we compared the impact of a heterozygous Sox9 null mutation (Sox9+/-) with the Sox9+/Y440X CD mutation that truncates the C-terminal transactivation domain but spares the DNA-binding domain. While some Sox9+/Y440X mice survived, all Sox9+/-mice died perinatally. However, the skeletal defects were more severe and IHH signaling in developing limb cartilage was significantly enhanced in Sox9+/Y440X compared with Sox9+/-. Activating Sox9Y440X specifically in the chondrocyte-osteoblast lineage caused milder campomelia, and revealed cell- and noncell autonomous mechanisms acting on chondrocyte differentiation and osteogenesis in the perichondrium. Transcriptome analyses of developing Sox9+/Y440X limbs revealed dysregulated expression of genes for the extracellular matrix, as well as changes consistent with aberrant WNT and HH signaling. SOX9Y440X failed to interact with ß-catenin and was unable to suppress transactivation of Ihh in cell-based assays. We propose enhanced HH signaling in the adjacent perichondrium induces asymmetrically localized excessive perichondrial osteogenesis resulting in campomelia. Our study implicates combined haploinsufficiency/hypomorphic and dominant-negative actions of SOX9Y440X, cell-autonomous and noncell autonomous mechanisms, and dysregulated WNT and HH signaling, as the cause of human campomelia. [ABSTRACT FROM AUTHOR]

Published

2023

2. SOX9 and SOX10 control fluid homeostasis in the inner ear for hearing through independent and cooperative mechanisms.

Author

Szeto, Irene Y. Y., Chu, Daniel K. H., Peikai Chen, Ka Chi Chu, Au, Tiffany Y. K., Leung, Keith K. H., Yong-Heng Huang, Wynn, Sarah L., Mak, Angel C. Y., Ying-Shing Chan, Wood Yee Chan, Jauch, Ralf, Fritzsch, Bernd, Mai Har Sham, Lovell-Badge, Robin, and Cheah, Kathryn S. E.

Subjects

SOX transcription factors, INNER ear, AQUAPORINS, TRANSCRIPTION factors, BLOOD coagulation factor IX

Abstract

The in vivo mechanisms underlying dominant syndromes caused by mutations in SRY-Box Transcription Factor 9 (SOX9) and SOX10 (SOXE) transcription factors, when they either are expressed alone or are coexpressed, are ill-defined. We created a mouse model for the campomelic dysplasia SOX9Y440X mutation, which truncates the transactivation domain but leaves DNA binding and dimerization intact. Here, we find that SOX9Y440X causes deafness via distinct mechanisms in the endolymphatic sac (ES)/duct and cochlea. By contrast, conditional heterozygous SoxS-null mice are normal. During the ES development of Sox9Y440X/+ heterozygotes, Sox10 and genes important for ionic homeostasis are down-regulated, and there is developmental persistence of progenitors, resulting in fewer mature cells. Sox10 heterozygous null mutants also display persistence of ES/duct progenitors. By contrast, SOX10 retains its expression in the early Sox9Y440X/+ mutant cochlea. Later, in the postnatal stria vascularis, dominant interference by SOX9Y440X is implicated in impairing the normal cooperation of SOX9 and SOX10 in repressing the expression of the water channel Aquaporin 3, thereby contributing to endolymphatic hydrops. Our study shows that for a functioning endolymphatic system in the inner ear, SOX9 regulates Sox10, and depending on the cell type and target gene, it works either independently of or cooperatively with SOX10. SOX9Y440X can interfere with the activity of both SOXE factors, exerting effects that can be classified as haploinsufficient/hypomorphic or dominant negative depending on the cell/gene context. This model of disruption of transcription factor partnerships may be applicable to congenital deafness, which affects ~0.3% of newborns, and other syndromic disorders. [ABSTRACT FROM AUTHOR]

Published

2022

3. Fbxo9 functions downstream of Sox10 to determine neuron-glial fate choice in the dorsal root ganglia through Neurog2 destabilization.

Author

Aijia Liu, Jessica, Tai, Andrew, Jialin Hong, May Pui Lai Cheung, Mai Har Sham, Cheah, Kathryn S. E., Chi Wai Cheung, and Cheung, Martin

Subjects

DORSAL root ganglia, NEURAL crest, NEUROGLIA, SENSORY neurons, CELL determination

Abstract

The transcription factor Sox10 is a key regulator in the fate determination of a subpopulation of multipotent trunk neural crest (NC) progenitors toward glial cells instead of sensory neurons in the dorsal root ganglia (DRG). However, the mechanism by which Sox10 regulates glial cell fate commitment during lineage segregation remains poorly understood. In our study, we showed that the neurogenic determinant Neurogenin 2 (Neurog2) exhibited transient overlapping expression with Sox10 in avian trunk NC progenitors, which progressively underwent lineage segregation during migration toward the forming DRG. Gain- and loss-of-function studies revealed that the temporary expression of Neurog2 was due to Sox10 regulation of its protein stability. Transcriptional profiling identified Sox10-regulated F-box only protein (Fbxo9), which is an SCF (Skp1-Cul-F-box)-type ubiquitin ligase for Neurog2. Consistently, overexpression of Fbxo9 in NC progenitors down-regulated Neurog2 protein expression through ubiquitination and promoted the glial lineage at the expense of neuronal differentiation, whereas Fbxo9 knockdown resulted in the opposite phenomenon. Mechanistically, we found that Fbxo9 interacted with Neurog2 to promote its destabilization through the F-box motif. Finally, epistasis analysis further demonstrated that Fbxo9 and probably other F-box members mediated the role of Sox10 in destabilizing Neurog2 protein and directing the lineage of NC progenitors toward glial cells rather than sensory neurons. Altogether, these findings unravel a Sox10-Fbxo9 regulatory axis in promoting the glial fate of NC progenitors through Neurog2 destabilization. [ABSTRACT FROM AUTHOR]

Published

2020

4. Hypertrophic chondrocytes can become osteoblasts and osteocytes in endochondral bone formation.

Author

Liu Yang, Kwok Yeung Tsang, Hoi Ching Tang, Danny Chan, and Cheah, Kathryn S. E.

Subjects

CARTILAGE cells, OSTEOBLASTS, BONE cells, PHYSIOLOGY, HOMEOSTASIS

Abstract

According to current dogma, chondrocytes and osteoblasts are considered independent lineages derived from a common osteochondroprogenitor. In endochondral bone formation, chondrocytes undergo a series of differentiation steps to form the growth plate, and it generally is accepted that death is the ultimate fate of terminally differentiated hypertrophic chondrocytes (HCs). Osteoblasts, accompanying vascular invasion, lay down endochondral bone to replace cartilage. However, whether an HC can become an osteoblast and contribute to the full osteogenic lineage has been the subject of a century-long debate. Here we use a cell-specific tamoxifen-inducible genetic recombination approach to track the fate of murine HCs and show that they can survive the cartilage-to-bone transition and become osteogenic cells in fetal and postnatal endochondral bones and persist into adulthood. This discovery of a chondrocyte-to-osteoblast lineage continuum revises concepts of the ontogeny of osteoblasts, with implications for the control of bone homeostasis and the interpretation of the underlying pathological bases of bone disorders. [ABSTRACT FROM AUTHOR]

Published

2014

5. Predicting the spatiotemporal dynamics of hair follicle patterns in the developing mouse.

Author

Chi Wa Cheng, Ben Niu, Warren, Mya, Pevny, Larysa Halyna, Lovell-Badge, Robin, Hwa, Terence, and Cheah, Kathryn S. E.

Subjects

EPITHELIUM, EMBRYOLOGY, HAIR follicles, DIFFUSION, GENETIC sex determination

Abstract

Reaction-diffusion models have been used as a paradigm for describing the de novo emergence of biological patterns such as stripes and spots. In many organisms, these initial patterns are typically refined and elaborated over the subsequent course of development. Here we study the formation of secondary hair follicle patterns in the skin of developing mouse embryos. We used the expression of sex-determining region Y box 2 to identify and distinguish the primary and secondary hair follicles and to infer the spatiotemporal dynamics of the follicle formation process. Quantitative analysis of the specific follicle patterns observed reveals a simple geometrical rule governing the formation of secondary follicles, and motivates an expansion-induction (EI) model in which new follicle formation is driven by the physical growth of the embryo. The EI model requires only one diffusible morphogen and provides quantitative, accurate predictions on the relative positions and timing of secondary follicle formation, using only the observed configuration of primary follicles as input. The same model accurately describes the positions of additional follicles that emerge from skin explants treated with an activator. Thus, the EI model provides a simple and robust mechanism for predicting secondary space-filling patterns in growing embryos. [ABSTRACT FROM AUTHOR]

Published

2014

6. Phosphorylation of Sox9 is required for neural crest delamination and is regulated downstream of BMP and canonical Wnt signaling.

Author

Liu, Jessica A. J., Ming-Hoi Wu, Yan, Carol H., Chau, Bolton K. H., So, Henry, Ng, Alvis, Chan, Alan, Cheah, Kathryn S. E., Briscoe, James, and Cheung, Martin

Subjects

PHOSPHORYLATION, NEURAL crest, TRANSCRIPTION factors, BONE morphogenetic proteins, LABORATORY mice, EXTRACELLULAR matrix

Abstract

Coordination of neural crest cell (NCC) induction and delamination is orchestrated by several transcription factors. Among these, Sry-related HMG box-9 (Sox9) and Snail2 have been implicated in both the induction of NCC identity and, together with phoshorylation, NCC delamination. How phosphorylation effects this function has not been clear. Here we show, in the developing chick neural tube, that phosphorylation of Sox9 on S64 and S181 facilitates its SUMOylation, and the phosphorylated forms of Sox9 are essential for trunk neural crest delamination. Both phosphorylation and to a lesser extent SUMOylation, of Sox9 are required to cooperate with Snail2 to promote delamination. Moreover, bone morphogenetic protein and canonical Wnt signaling induce phosphorylation of Sox9, thereby connecting extracellular signals with the delamination of NCCs. Together the data suggest a model in which extracellular signals initiate phosphorylation of Sox9 and its cooperation with Snail2 to induce NCC delamination. [ABSTRACT FROM AUTHOR]

Published

2013

7. Sox2 signaling in prosensory domain specification and subsequent hair cell differentiation in the developing cochlea.

Author

Dabdoub, Alain, PuIigiIIa, Chandrakala, Jones, Jennifer M., Fritzsch, Bernd, Cheah, Kathryn S. E., Pevny, Larysa H., and Kelley, Matthew W.

Subjects

CELL differentiation, COCHLEA, GENETIC mutation, DEAFNESS, HAIR cells

Abstract

Sox2 is a high-mobility transcription factor that is one of the earliest markers of developing inner ear prosensory domains. In humans, mutations in SOX2 cause sensorineural hearing loss and a loss of function study in mice showed that Sox2 is required for prosensory formation in the cochlea. However, the specific roles of Sox2 have not been determined. Here we illustrate a dynamic role of Sox2 as an early permissive factor in prosensory domain formation followed by a mutually antagonistic relationship with Atoh1, a bHLH protein necessary for hair cell development. We demonstrate that decreased levels of Sox2 result in precocious hair cell differentiation and an over production of inner hair cells and that these effects are likely mediated through an antagonistic interaction between Sox2 and the bHLH molecule Atoh1. Using gain-and loss-of-function experiments we provide evidence for the molecular pathway responsible for the formation of the cochlear prosensory domain. Sox2 expression is promoted by Notch signaling and Proxi, a homeobox transcription factor, is a downstream target of Sox2. These results demonstrate crucial and diverse roles for Sox2 in the development, specification. and maintenance of sensory cells within the cochlea. [ABSTRACT FROM AUTHOR]

Published

2008

8. Increased efficiency of oligonucleotide-mediated gene repair through slowing replication fork progression.

Author

Wu, Xue-Song, Xin, Li, Yi, Wen-Xuan, Xi-Ying Shang, Lu, Lu, Watt, Rory M., Cheah, Kathryn S. E., Huang, Jian-Dong, Liu, De-Pei, and Chih-Chuan Liang

Subjects

OLIGONUCLEOTIDES, GENOMICS, GENE therapy, CELL cycle, MAMMALS, GENETIC engineering

Abstract

Targeted gene modification mediated by single-stranded oligonucleotides (SSOs) holds great potential for widespread use in a number of biological and biomedical fields, including functional genomics and gene therapy. By using this approach, specific genetic changes have been created in a number of prokaryotic and eukaryotic systems. In mammalian cells, the precise mechanism of 550-mediated chromosome alteration remains to be established, and there have been problems in obtaining reproducible targeting efficiencies. It has previously been suggested that the chromatin structure, which changes throughout the cell cycle, may be a key factor underlying these variations in efficiency. This hypothesis prompted us to systematically investigate SSO-mediated gene repair at various phases of the cell cycle in a mammalian cell line. We found that the efficiency of SSO-mediated gene repair was elevated by ≈10-foId in thymidine-treated S-phase cells. The increase in repair frequency correlated positively with the duration of SSO/thymidine coincubation with host cells after transfection. We supply evidence suggesting that these increased repair frequencies arise from a thymidine-induced slowdown of replication fork progression. Our studies provide fresh insight into the mechanism of SSO-mediated gene repair in mammalian cells and demonstrate how its efficiency may be reliably and substantially increased. [ABSTRACT FROM AUTHOR]

Published

2005

9. Fbxo9 functions downstream of Sox10 to determine neuron-glial fate choice in the dorsal root ganglia through Neurog2 destabilization.

Author

Liu JA, Tai A, Hong J, Cheung MPL, Sham MH, Cheah KSE, Cheung CW, and Cheung M

Subjects

Amino Acid Motifs, Animals, Basic Helix-Loop-Helix Transcription Factors chemistry, Basic Helix-Loop-Helix Transcription Factors genetics, Chick Embryo, F-Box Proteins chemistry, F-Box Proteins genetics, Female, Gene Expression Regulation, Developmental, Male, Mice, Mice, Knockout, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins genetics, Neural Crest cytology, Neural Crest metabolism, Neurogenesis, Protein Binding, Protein Stability, Spinal Nerve Roots cytology, Basic Helix-Loop-Helix Transcription Factors metabolism, F-Box Proteins metabolism, Nerve Tissue Proteins metabolism, Neuroglia cytology, Neuroglia metabolism, Neurons cytology, Neurons metabolism, SOXE Transcription Factors metabolism, Spinal Nerve Roots metabolism

Abstract

The transcription factor Sox10 is a key regulator in the fate determination of a subpopulation of multipotent trunk neural crest (NC) progenitors toward glial cells instead of sensory neurons in the dorsal root ganglia (DRG). However, the mechanism by which Sox10 regulates glial cell fate commitment during lineage segregation remains poorly understood. In our study, we showed that the neurogenic determinant Neurogenin 2 (Neurog2) exhibited transient overlapping expression with Sox10 in avian trunk NC progenitors, which progressively underwent lineage segregation during migration toward the forming DRG. Gain- and loss-of-function studies revealed that the temporary expression of Neurog2 was due to Sox10 regulation of its protein stability. Transcriptional profiling identified Sox10-regulated F-box only protein (Fbxo9), which is an SCF (Skp1-Cul-F-box)-type ubiquitin ligase for Neurog2. Consistently, overexpression of Fbxo9 in NC progenitors down-regulated Neurog2 protein expression through ubiquitination and promoted the glial lineage at the expense of neuronal differentiation, whereas Fbxo9 knockdown resulted in the opposite phenomenon. Mechanistically, we found that Fbxo9 interacted with Neurog2 to promote its destabilization through the F-box motif. Finally, epistasis analysis further demonstrated that Fbxo9 and probably other F-box members mediated the role of Sox10 in destabilizing Neurog2 protein and directing the lineage of NC progenitors toward glial cells rather than sensory neurons. Altogether, these findings unravel a Sox10-Fbxo9 regulatory axis in promoting the glial fate of NC progenitors through Neurog2 destabilization., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

10. Hypertrophic chondrocytes can become osteoblasts and osteocytes in endochondral bone formation.

Author

Yang L, Tsang KY, Tang HC, Chan D, and Cheah KS

Subjects

Animals, Cell Lineage, Mice, Bone Development, Cell Differentiation, Chondrocytes cytology, Osteoblasts cytology, Osteocytes cytology

Abstract

According to current dogma, chondrocytes and osteoblasts are considered independent lineages derived from a common osteochondroprogenitor. In endochondral bone formation, chondrocytes undergo a series of differentiation steps to form the growth plate, and it generally is accepted that death is the ultimate fate of terminally differentiated hypertrophic chondrocytes (HCs). Osteoblasts, accompanying vascular invasion, lay down endochondral bone to replace cartilage. However, whether an HC can become an osteoblast and contribute to the full osteogenic lineage has been the subject of a century-long debate. Here we use a cell-specific tamoxifen-inducible genetic recombination approach to track the fate of murine HCs and show that they can survive the cartilage-to-bone transition and become osteogenic cells in fetal and postnatal endochondral bones and persist into adulthood. This discovery of a chondrocyte-to-osteoblast lineage continuum revises concepts of the ontogeny of osteoblasts, with implications for the control of bone homeostasis and the interpretation of the underlying pathological bases of bone disorders.

Published

2014

11. Predicting the spatiotemporal dynamics of hair follicle patterns in the developing mouse.

Author

Cheng CW, Niu B, Warren M, Pevny LH, Lovell-Badge R, Hwa T, and Cheah KS

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Body Patterning, Carrier Proteins metabolism, Computer Simulation, Galactosides, Histological Techniques, Indoles, Mice, Hair Follicle embryology, Models, Biological, Morphogenesis physiology

Abstract

Reaction-diffusion models have been used as a paradigm for describing the de novo emergence of biological patterns such as stripes and spots. In many organisms, these initial patterns are typically refined and elaborated over the subsequent course of development. Here we study the formation of secondary hair follicle patterns in the skin of developing mouse embryos. We used the expression of sex-determining region Y box 2 to identify and distinguish the primary and secondary hair follicles and to infer the spatiotemporal dynamics of the follicle formation process. Quantitative analysis of the specific follicle patterns observed reveals a simple geometrical rule governing the formation of secondary follicles, and motivates an expansion-induction (EI) model in which new follicle formation is driven by the physical growth of the embryo. The EI model requires only one diffusible morphogen and provides quantitative, accurate predictions on the relative positions and timing of secondary follicle formation, using only the observed configuration of primary follicles as input. The same model accurately describes the positions of additional follicles that emerge from skin explants treated with an activator. Thus, the EI model provides a simple and robust mechanism for predicting secondary space-filling patterns in growing embryos.

Published

2014