Your search keyword '"Singh, Pratik"' showing total 4 results

1. Molecular mechanism of synovial joint site specification and induction in developing vertebrate limbs.

Author

Yadav, Upendra S., Biswas, Tathagata, Singh, Pratik N., Gupta, Pankaj, Chakraborty, Soura, Delgado, Irene, Zafar, Hamim, Capellini, Terence D., Torres, Miguel, and Bandyopadhyay, Amitabha

Subjects

JOINTS (Anatomy), FIBROBLAST growth factors, BUD development

Abstract

The vertebrate appendage comprises three primary segments, the stylopod, zeugopod and autopod, each separated by joints. The molecular mechanisms governing the specification of joint sites, which define segment lengths and thereby limb architecture, remain largely unknown. Existing literature suggests that reciprocal gradients of retinoic acid (RA) and fibroblast growth factor (FGF) signaling define the expression domains of the putative segment markers Meis1, Hoxa11 and Hoxa13. Barx1 is expressed in the presumptive joint sites. Our data demonstrate that RA-FGF signaling gradients define the expression domain of Barx1 in the first presumptive joint site. When misexpressed, Barx1 induces ectopic interzone-like structures, and its loss of function partially blocks interzone development. Simultaneous perturbations of RA-FGF signaling gradients result in predictable shifts of Barx1 expression domains along the proximo-distal axis and, consequently, in the formation of repositioned joints. Our data suggest that during early limb bud development in chick, Meis1 and Hoxa11 expression domains are overlapping, whereas the Barx1 expression domain resides within the Hoxa11 expression domain. However, once the interzone is formed, the expression domains are refined and the Barx1 expression domain becomes congruent with the border of these two putative segment markers. [ABSTRACT FROM AUTHOR]

Published

2023

2. NFIA and GATA3 are crucial regulators of embryonic articular cartilage differentiation.

Author

Singh, Pratik Narendra Pratap, Yadav, Upendra Singh, Azad, Kimi, Goswami, Pooja, Kinare, Veena, and Bandyopadhyay, Amitabha

Subjects

*CARTILAGE regeneration, *ARTICULAR cartilage

Abstract

During appendicular skeletal development, the bi-potential cartilage anlagen gives rise to transient cartilage, which is eventually replaced by bone, and to articular cartilage that caps the ends of individual skeletal elements. While the molecular mechanism that regulates transient cartilage differentiation is relatively well understood, the mechanism of articular cartilage differentiation has only begun to be unraveled. Furthermore, the molecules that coordinate the articular and transient cartilage differentiation processes are poorly understood. Here, we have characterized in chick the regulatory roles of two transcription factors, NFIA and GATA3, in articular cartilage differentiation, maintenance and the coordinated differentiation of articular and transient cartilage. Both NFIA and GATA3 block hypertrophic differentiation. Our results suggest that NFIA is not sufficient but necessary for articular cartilage differentiation. Ectopic activation of GATA3promotes articular cartilage differentiation, where as inhibition of GATA3 activity promotes transient cartilage differentiation at the expense of articular cartilage. We propose a novel transcriptional circuitry involved in embryonic articular cartilage differentiation, maintenance and its crosstalk with the transient cartilage differentiation program. [ABSTRACT FROM AUTHOR]

Published

2018

3. NFIA and GATA3, critical regulators of embryonic articular cartilage differentiation.

Author

Singh, Pratik Narendra Pratap, Yadav, Upendra Singh, Azad, Kimi, Goswami, Pooja, Kinare, Veena, and Bandyopadhyay, Amitabha

Subjects

*ARTICULAR cartilage, *GENETIC regulation, *CELL differentiation

Abstract

During appendicular skeletal development, the bi-potential cartilage anlagen gives rise to transient cartilage, which is eventually replaced by bone, and articular cartilage which caps the ends of individual skeletal elements. While the molecular mechanism that regulates transient cartilage differentiation is relatively better understood, the mechanism of articular cartilage differentiation has only begun to be unraveled. Further, the molecules that coordinate articular and transient cartilage differentiation processes are very poorly understood. Here, we have characterized the regulatory roles of two transcription factors, NFIA and GATA3 in articular cartilage differentiation, maintenance and the coordinated differentiation of articular and transient cartilage. Both NFIA and GATA3 block hypertrophic differentiation. Our results suggest that NFIA is not sufficient but necessary for articular cartilage differentiation. On the other hand, while ectopic activation of GATA3 promotes articular cartilage differentiation, inhibition of GATA3 activity promotes transient cartilage differentiation at the expense of articular cartilage. Finally, we propose a novel transcriptional circuitry involved in embryonic articular cartilage differentiation, maintenance and its crosstalk with transient cartilage differentiation program. [ABSTRACT FROM AUTHOR]

Published

2017

4. Precise spatial restriction of BMP signaling is essential for articular cartilage differentiation.

Author

Ray, Ayan, Singh, Pratik Narendra Pratap, Sohaskey, Michael L., Harland, Richard M., and Bandyopadhyay, Amitabha

Subjects

*ARTICULAR cartilage, *CARTILAGE, *LIGAMENTS, *CELL proliferation, *CELL cycle

Abstract

The articular cartilage, which lines the joints of the limb skeleton, is distinct from the adjoining transient cartilage, and yet, it differentiates as a unique population within a contiguous cartilage element. Current literature suggests that articular cartilage and transient cartilage originate from different cell populations. Using a combination of lineage tracing and pulse-chase of actively proliferating chondrocytes, we here demonstrate that, similar to transient cartilage, embryonic articular cartilage cells also originate from the proliferating chondrocytes situated near the distal ends of skeletal anlagen. We show that nascent cartilage cells are capable of differentiating as articular or transient cartilage, depending on exposure to Wnt or BMP signaling, respectively. The spatial organization of the articular cartilage results from a band of Nogexpressing cells, which insulates these proliferating chondrocytes from BMP signaling and allows them to differentiate as articular cartilage under the influence of Wnt signaling emanating from the interzone. Through experiments conducted in both chick and mouse embryos we have developed a model explaining simultaneous growth and differentiation of transient and articular cartilage in juxtaposed domains. [ABSTRACT FROM AUTHOR]

Published

2015