Your search keyword '"Bercowsky Rama, Arianne"' showing total 4 results

1. Python: Data Handling, Analysis and Plotting

Author

Bercowsky Rama, Arianne, Bosserhoff, Anja K., Series Editor, Berenjian, Aydin, Series Editor, Carbonell, Pablo, Series Editor, Levite, Mia, Series Editor, Roig, Joan, Series Editor, Turksen, Kursad, Series Editor, Miura, Kota, editor, and Sladoje, Nataša, editor

Published

2022

2. Cell-autonomous timing drives the vertebrate segmentation clock's wave pattern.

Author

Rohde, Laurel A., Bercowsky-Rama, Arianne, Valentin, Guillaume, Naganathan, Sundar Ram, Desai, Ravi A., Strnad, Petr, Soroldoni, Daniele, and Oates, Andrew C.

Subjects

*SEGMENTATION (Biology), *DEVELOPMENTAL programs, *GENE expression, *MESODERM, *TIME management

Abstract

Rhythmic and sequential segmentation of the growing vertebrate body relies on the segmentation clock, a multi-cellular oscillating genetic network. The clock is visible as tissue-level kinematic waves of gene expression that travel through the presomitic mesoderm (PSM) and arrest at the position of each forming segment. Here, we test how this hallmark wave pattern is driven by culturing single maturing PSM cells. We compare their cell-autonomous oscillatory and arrest dynamics to those we observe in the embryo at cellular resolution, finding similarity in the relative slowing of oscillations and arrest in concert with differentiation. This shows that cell-extrinsic signals are not required by the cells to instruct the developmental program underlying the wave pattern. We show that a cell-autonomous timing activity initiates during cell exit from the tailbud, then runs down in the anterior-ward cell flow in the PSM, thereby using elapsed time to provide positional information to the clock. Exogenous FGF lengthens the duration of the cell-intrinsic timer, indicating extrinsic factors in the embryo may regulate the segmentation clock via the timer. In sum, our work suggests that a noisy cell-autonomous, intrinsic timer drives the slowing and arrest of oscillations underlying the wave pattern, while extrinsic factors in the embryo tune this timer's duration and precision. This is a new insight into the balance of cell-intrinsic and -extrinsic mechanisms driving tissue patterning in development. [ABSTRACT FROM AUTHOR]

Published

2024

3. Understanding the role of signaling in pattern formation in mouse embryonic organoids

Author

Bercowsky Rama, Arianne

Subjects

Cèl·lules mare -- Investigació, Embryonic stem cells, Reaction diffusion, Embrió humà -- Investigació, Pattern

Abstract

Treball de fi de grau en Biomèdica Tutors: Jordi Gacía Ojalvo, Alfonso Martínez Arias Small aggregates of 300-500 mouse embryonic stem cells are able to self-organize into polarized structures that exhibit collective behavior that mirrors those observed in early mouse embryos. This includes symmetry breaking, axial organization, germ layer specification and axis elongation on a time-scale similar to that of the mouse embryo. These embryonic organoids are called Gastruloids and are a reproducible model system to understand the processes underlying early mouse development. These Gastruloids were formed from mouse embryonic stem cells containing reporters for T-Brachyury, and FGF Signaling. We were able to quantitatively assess the contribution of these signaling pathways to the establishment of a pattern in early gastrulogenesis through single time-point and live-cell fluorescence microscopy. We found that during the first 24h-48h of culture, interactions between the Wnt/- Catenin signaling pathways promote the initial symmetry-breaking event (elongation), manifested through polarized T-Brachyury expression. Our experiments also show that FGF/MEK signaling pathway does not play an important role in pattern formation or in Gastruloid elongation although we suspect that another FGF signaling pathway might be crucial for these events to happen. However, more experimental work should be done to better understand which FGF pathway is really involved in early gastrulogenesis. We can conclude that chemical signaling plays an important role in pattern formation but the mechanical interactions between cells is also relevant for this process to take place. From these experimental observations, we tried to model T-Brachyury pattern formation in Gastruloids using the reaction-di↵usion model from Alan Turing, which is the best known theoretical model used to explain self-regulated pattern formation in the developing animal embryo. We performed the stability analysis for a two component and a three component system were we imposed that only two molecules were able to di↵use. Also, we included time delay in the typical Gierer-Meinhardt models to see whether pattern could still be able to form. As a result, we showed that any two component reaction di↵usion system with only one di↵user cannot exhibit Turing instabilities and the addition of a third di↵user in our system failed to become a Turing system because of our network structure. With all the stability analysis performed, we created a tool used to reject three component systems with two di↵users from being Turing patterns just by looking at the network structure. Finally, we were able to observe how a small time delay in protein production was able to avoid pattern formation in the most used reaction-di↵usion systems. The experimental and computational results suggest that pattern formation is a process that requires mechanical transduction and time delay due to protein formation, so as a future work we shall focus on a di↵erent modeling approach.

Published

2017

4. Hunting for the wavefront: investigation of somite boundary positioning in zebrafish

Author

Bercowsky Rama, Arianne and Oates, Andrew Charles

Subjects

cell-tracking, python, Somitogenesis, clock, microscopy, zebrafish

Abstract

Somitogenesis is the rhythmic and sequential formation of somites, which are tissue blocks that give rise to segmented adult body structures including the vertebrae and associated muscle. Somite formation is controlled by the segmentation clock, a population of genetic oscillators that are coordinated by an interplay of cell-intrinsic and -extrinsic spatiotemporal information. Disruption of the segmentation clock can lead to misplaced or defective somite boundaries, and consequently results in deformed adult structures (e.g., congenital scoliosis). Despite decades of research into how the segmentation clock pattern is established, and how it acts to position somite boundaries within the pre-segmental mesoderm(PSM), many open questions remain. The position where the somite boundary is set along the anteroposterior axis of the PSM has been named the "determination front". Question still remain as to the mechanism and location of the determination front, and what spatiotemporal information is instructive. Here I present three studies that tackle this question by advancing imaging and analysis tools such that questions that have persisted for decades can be directly addressed. My work contributed significantly to obtaining a better picture of how somite boundaries are precisely formed.