Your search keyword '"Menshykau D"' showing total 5 results

1. Image-based modeling of kidney branching morphogenesis reveals GDNF-RET based Turing-type mechanism and pattern-modulating WNT11 feedback.

Author

Menshykau D, Michos O, Lang C, Conrad L, McMahon AP, and Iber D

Subjects

Animals, Bacterial Proteins chemistry, Bacterial Proteins genetics, Computer Simulation, Embryo, Mammalian, Feedback, Physiological, Female, Image Processing, Computer-Assisted, Kidney diagnostic imaging, Luminescent Proteins chemistry, Luminescent Proteins genetics, Mice, Mice, Transgenic, Microscopy, Fluorescence methods, Organ Culture Techniques, Signal Transduction physiology, Time-Lapse Imaging methods, Tomography, Optical methods, Glial Cell Line-Derived Neurotrophic Factor metabolism, Kidney growth & development, Models, Biological, Organogenesis, Proto-Oncogene Proteins c-ret metabolism, Wnt Proteins metabolism

Abstract

Branching patterns and regulatory networks differ between branched organs. It has remained unclear whether a common regulatory mechanism exists and how organ-specific patterns can emerge. Of all previously proposed signalling-based mechanisms, only a ligand-receptor-based Turing mechanism based on FGF10 and SHH quantitatively recapitulates the lung branching patterns. We now show that a GDNF-dependent ligand-receptor-based Turing mechanism quantitatively recapitulates branching of cultured wildtype and mutant ureteric buds, and achieves similar branching patterns when directing domain outgrowth in silico. We further predict and confirm experimentally that the kidney-specific positive feedback between WNT11 and GDNF permits the dense packing of ureteric tips. We conclude that the ligand-receptor based Turing mechanism presents a common regulatory mechanism for lungs and kidneys, despite the differences in the molecular implementation. Given its flexibility and robustness, we expect that the ligand-receptor-based Turing mechanism constitutes a likely general mechanism to guide branching morphogenesis and other symmetry breaks during organogenesis.

Published

2019

2. An interplay of geometry and signaling enables robust lung branching morphogenesis.

Author

Menshykau D, Blanc P, Unal E, Sapin V, and Iber D

Subjects

Animals, Mice, Time-Lapse Imaging, Fibroblast Growth Factor 10 metabolism, Hedgehog Proteins metabolism, Lung embryology, Models, Biological, Morphogenesis physiology, Signal Transduction physiology

Abstract

Early branching events during lung development are stereotyped. Although key regulatory components have been defined, the branching mechanism remains elusive. We have now used a developmental series of 3D geometric datasets of mouse embryonic lungs as well as time-lapse movies of cultured lungs to obtain physiological geometries and displacement fields. We find that only a ligand-receptor-based Turing model in combination with a particular geometry effect that arises from the distinct expression domains of ligands and receptors successfully predicts the embryonic areas of outgrowth and supports robust branch outgrowth. The geometry effect alone does not support bifurcating outgrowth, while the Turing mechanism alone is not robust to noisy initial conditions. The negative feedback between the individual Turing modules formed by fibroblast growth factor 10 (FGF10) and sonic hedgehog (SHH) enlarges the parameter space for which the embryonic growth field is reproduced. We therefore propose that a signaling mechanism based on FGF10 and SHH directs outgrowth of the lung bud via a ligand-receptor-based Turing mechanism and a geometry effect., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

3. Feedback, receptor clustering, and receptor restriction to single cells yield large Turing spaces for ligand-receptor-based Turing models.

Author

Kurics T, Menshykau D, and Iber D

Subjects

Feedback, Physiological, Fibroblast Growth Factor 10 metabolism, Hedgehog Proteins metabolism, Lung anatomy & histology, Lung metabolism, Protein Binding, Ligands, Models, Biological, Receptors, Cell Surface metabolism

Abstract

Turing mechanisms can yield a large variety of patterns from noisy, homogenous initial conditions and have been proposed as patterning mechanism for many developmental processes. However, the molecular components that give rise to Turing patterns have remained elusive, and the small size of the parameter space that permits Turing patterns to emerge makes it difficult to explain how Turing patterns could evolve. We have recently shown that Turing patterns can be obtained with a single ligand if the ligand-receptor interaction is taken into account. Here we show that the general properties of ligand-receptor systems result in very large Turing spaces. Thus, the restriction of receptors to single cells, negative feedbacks, regulatory interactions among different ligand-receptor systems, and the clustering of receptors on the cell surface all greatly enlarge the Turing space. We further show that the feedbacks that occur in the FGF10-SHH network that controls lung branching morphogenesis are sufficient to result in large Turing spaces. We conclude that the cellular restriction of receptors provides a mechanism to sufficiently increase the size of the Turing space to make the evolution of Turing patterns likely. Additional feedbacks may then have further enlarged the Turing space. Given their robustness and flexibility, we propose that receptor-ligand-based Turing mechanisms present a general mechanism for patterning in biology.

Published

2014

4. Species-specific differences in follicular antral sizes result from diffusion-based limitations on the thickness of the granulosa cell layer.

Author

Bächler M, Menshykau D, De Geyter Ch, and Iber D

Subjects

Adult, Animals, Body Size, Cell Size, Computer Simulation, Diffusion, Estradiol metabolism, Female, Follicle Stimulating Hormone metabolism, Gonadotropins metabolism, Granulosa Cells physiology, Humans, Mammals, Oocytes cytology, Oocytes physiology, Species Specificity, Follicular Fluid physiology, Granulosa Cells cytology, Models, Biological

Abstract

The size of mature oocytes is similar across mammalian species, yet the size of ovarian follicles increases with species size, with some ovarian follicles reaching diameters>1000-fold the size of the enclosed oocyte. Here we show that the different follicular sizes can be explained with diffusion-based limitations on the thickness of the hormone-secreting granulosa layer. By analysing published data on human follicular growth and granulosa cell expansion during follicular maturation we find that the 4-fold increase of the antral follicle diameter is entirely driven by an increase in the follicular fluid volume, while the thickness of the surrounding granulosa layer remains constant at ∼45±10 µm. Based on the measured kinetic constants, the model reveals that the observed fall in the gonadotrophin concentration from peripheral blood circulation to the follicular antrum is a result of sequestration in the granulosa. The model further shows that as a result of sequestration, an increased granulosa thickness cannot substantially increase estradiol production but rather deprives the oocyte from gonadotrophins. Larger animals (with a larger blood volume) require more estradiol as produced by the ovaries to down-regulate follicle-stimulating hormone-secretion in the pituitary. Larger follicle diameters result in larger follicle surface areas for constant granulosa layer thickness. The reported increase in the follicular surface area in larger species indeed correlates linearly both with species mass and with the predicted increase in estradiol output. In summary, we propose a structural role for the antrum in that it determines the volume of the granulosa layer and thus the level of estrogen production.

Published

2014

5. Kidney branching morphogenesis under the control of a ligand-receptor-based Turing mechanism.

Author

Menshykau D and Iber D

Subjects

Animals, Body Patterning genetics, Body Patterning physiology, Computational Biology methods, Gene Expression Regulation, Developmental, Kidney metabolism, Ligands, Linear Models, Lung embryology, Lung metabolism, Mice, Morphogenesis genetics, Protein Binding, Wnt Proteins genetics, Glial Cell Line-Derived Neurotrophic Factor genetics, Glial Cell Line-Derived Neurotrophic Factor Receptors genetics, Kidney embryology, Models, Biological, Morphogenesis physiology, Proto-Oncogene Proteins c-ret genetics

Abstract

The main signalling proteins that control early kidney branching have been defined. Yet the underlying mechanism is still elusive. We have previously shown that a Schnakenberg-type Turing mechanism can recapitulate the branching and protein expression patterns in wild-type and mutant lungs, but it is unclear whether this mechanism would extend to other branched organs that are regulated by other proteins. Here, we show that the glial cell line-derived neurotrophic factor-RET regulatory interaction gives rise to a Schnakenberg-type Turing model that reproduces the observed budding of the ureteric bud from the Wolffian duct, its invasion into the mesenchyme and the observed branching pattern. The model also recapitulates all relevant protein expression patterns in wild-type and mutant mice. The lung and kidney models are both based on a particular receptor-ligand interaction and require (1) cooperative binding of ligand and receptor, (2) a lower diffusion coefficient for the receptor than for the ligand and (3) an increase in the receptor concentration in response to receptor-ligand binding (by enhanced transcription, more recycling or similar). These conditions are met also by other receptor-ligand systems. We propose that ligand-receptor-based Turing patterns represent a general mechanism to control branching morphogenesis and other developmental processes.

Published

2013