Your search keyword '"Hendrik B Tiedemann"' showing total 4 results

1. Modeling coexistence of oscillation and Delta/Notch-mediated lateral inhibition in pancreas development and neurogenesis

Author

Elida Schneltzer, Johannes Beckers, Hendrik B. Tiedemann, Gerhard K. H. Przemeck, and Martin Hrabě de Angelis

Subjects

0301 basic medicine, Statistics and Probability, endocrine system, medicine.medical_specialty, Neurogenesis, Gene regulatory network, Endocrine System, Nerve Tissue Proteins, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, Lateral inhibition, Oscillometry, Internal medicine, Gene expression, Basic Helix-Loop-Helix Transcription Factors, medicine, Animals, Cell Lineage, HES1, Pancreas, Body Patterning, Progenitor, Feedback, Physiological, Pancreatic duct, Receptors, Notch, General Immunology and Microbiology, Applied Mathematics, Gene Expression Regulation, Developmental, General Medicine, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Endocrinology, Modeling and Simulation, Transcription Factor HES-1, General Agricultural and Biological Sciences, Neurog3, Pancreatogenesis, Cycling Gene Expression, Endocrine Progenitor, Simulation

Abstract

During pancreas development, Neurog3 positive endocrine progenitors are specified by Delta/Notch (D/N) mediated lateral inhibition in the growing ducts. During neurogenesis, genes that determine the transition from the proneural state to neuronal or glial lineages are oscillating before their expression is sustained. Although the basic gene regulatory network is very similar, cycling gene expression in pancreatic development was not investigated yet, and previous simulations of lateral inhibition in pancreas development excluded by design the possibility of oscillations. To explore this possibility, we developed a dynamic model of a growing duct that results in an oscillatory phase before the determination of endocrine progenitors by lateral inhibition. The basic network (D/N + Hes1 + Neurog3) shows scattered, stable Neurog3 expression after displaying transient expression. Furthermore, we included the Hes1 negative feedback as previously discussed in neurogenesis and show the consequences for Neurog3 expression in pancreatic duct development. Interestingly, a weakened HES1 action on the Hes1 promoter allows the coexistence of stable patterning and oscillations. In conclusion, cycling gene expression and lateral inhibition are not mutually exclusive. In this way, we argue for a unified mode of D/N mediated lateral inhibition in neurogenic and pancreatic progenitor specification.

Published

2017

2. Fast synchronization of ultradian oscillators controlled by delta-notch signaling with cis-inhibition

Author

Hendrik B. Tiedemann, Elida Schneltzer, Stefan Zeiser, Gerhard K. H. Przemeck, Johannes Beckers, Wolfgang Wurst, and Martin Hrabě de Angelis

Subjects

Gene regulatory network, Notch signaling pathway, Biology, Topology, Cellular and Molecular Neuroscience, Mice, Biological Clocks, Somitogenesis, Genetics, medicine, Paraxial mesoderm, Basic Helix-Loop-Helix Transcription Factors, Animals, Gene Regulatory Networks, RNA, Messenger, Receptor, Notch1, lcsh:QH301-705.5, Molecular Biology, Theoretical Biology, Ecology, Evolution, Behavior and Systematics, Ecology, Models, Genetic, Intracellular Signaling Peptides and Proteins, Computational Biology, Membrane Proteins, Biology and Life Sciences, Somite, medicine.anatomical_structure, lcsh:Biology (General), Computational Theory and Mathematics, Cytoplasm, Modeling and Simulation, Signal transduction, Entrainment (chronobiology), Signal Transduction, Research Article, Developmental Biology

Abstract

While it is known that a large fraction of vertebrate genes are under the control of a gene regulatory network (GRN) forming a clock with circadian periodicity, shorter period oscillatory genes like the Hairy-enhancer-of split (Hes) genes are discussed mostly in connection with the embryonic process of somitogenesis. They form the core of the somitogenesis-clock, which orchestrates the periodic separation of somites from the presomitic mesoderm (PSM). The formation of sharp boundaries between the blocks of many cells works only when the oscillators in the cells forming the boundary are synchronized. It has been shown experimentally that Delta-Notch (D/N) signaling is responsible for this synchronization. This process has to happen rather fast as a cell experiences at most five oscillations from its ‘birth’ to its incorporation into a somite. Computer simulations describing synchronized oscillators with classical modes of D/N-interaction have difficulties to achieve synchronization in an appropriate time. One approach to solving this problem of modeling fast synchronization in the PSM was the consideration of cell movements. Here we show that fast synchronization of Hes-type oscillators can be achieved without cell movements by including D/N cis-inhibition, wherein the mutual interaction of DELTA and NOTCH in the same cell leads to a titration of ligand against receptor so that only one sort of molecule prevails. Consequently, the symmetry between sender and receiver is partially broken and one cell becomes preferentially sender or receiver at a given moment, which leads to faster entrainment of oscillators. Although not yet confirmed by experiment, the proposed mechanism of enhanced synchronization of mesenchymal cells in the PSM would be a new distinct developmental mechanism employing D/N cis-inhibition. Consequently, the way in which Delta-Notch signaling was modeled so far should be carefully reconsidered., Author Summary During vertebrate embryonic development, the segmented structure of the axial skeleton is laid down by the process of somitogenesis. Periodically, blocks of cells separate at the anterior end of a mesenchymal tissue (PSM) on either side of the neural tube and develop later into spinal vertebrae. Cellular oscillators operating in each cell of the PSM control this process. Their synchronization is essential, and is effected by direct cell-to-cell signaling of the Delta/Notch (D/N) pathway. To better understand the regulation of the genes involved, we employ computer modeling. In this case, the fast synchronization of the oscillators represents a special challenging and worked so far only by the integration of cell movements. Now, we have succeeded in accelerating the synchronization for the first time without cell movements by the interposition of the novel mechanism of intracellular reciprocal inhibition termed D/N cis-inhibition into our computer simulations.

Published

2014

3. Cell-based simulation of dynamic expression patterns in the presomitic mesoderm

Author

Johannes Beckers, Martin Hrabé de Angelis, Elida Schneltzer, Isabel Rubio-Aliaga, Stefan Zeiser, Hendrik B. Tiedemann, Gerhard K. H. Przemeck, and Wolfgang Wurst

Subjects

Statistics and Probability, Gene regulatory network, Biology, Bioinformatics, General Biochemistry, Genetics and Molecular Biology, Mesoderm, FGF8, Negative feedback, Somitogenesis, Paraxial mesoderm, Animals, Segmentation, Computer Simulation, HES1, General Immunology and Microbiology, Models, Genetic, Receptors, Notch, Applied Mathematics, Intracellular Signaling Peptides and Proteins, Clock and wavefront model, Gene Expression Regulation, Developmental, Membrane Proteins, Object-oriented modelling, Hes1, Fgf8 gradient, Delta–Notch signalling, General Medicine, Cell biology, Somites, Modeling and Simulation, embryonic structures, Vertebrates, General Agricultural and Biological Sciences, Signal Transduction

Abstract

To model dynamic expression patterns in somitogenesis we developed a Java-application for simulating gene regulatory networks in many cells in parallel and visualising the results using the Java3D API, thus simulating the collective behaviour of many thousand cells. According to the ‘clock-and-wave-front’ model mesodermal segmentation of vertebrate embryos is regulated by a ‘segmentation clock’, which oscillates with a period of about 2 h in mice, and a ‘wave front’ moving back with the growing caudal end of the presomitic mesoderm. The clock is realised through cycling expression of genes such as Hes1 and Hes7, whose gene products repress the transcription of their encoding genes in a negative feedback loop. By coupling the decay of the Hes1 mRNA to a gradient with the same features and mechanism of formation as the mesodermal Fgf8 gradient we can simulate typical features of the dynamic expression pattern of Hes1 in the presomitic mesoderm. Furthermore, our program is able to synchronise Hes1 oscillations in thousands of cells through simulated Delta–Notch signalling interactions.

Published

2006

4. From Dynamic Expression Patterns to Boundary Formation in the Presomitic Mesoderm

Author

Johannes Beckers, Martin Hrabě de Angelis, Hendrik B. Tiedemann, Gerhard K. H. Przemeck, Stefan Zeiser, Elida Schneltzer, and Bastian Hoesel

Subjects

Embryology, Mesoderm, Notch signaling pathway, Gene regulatory network, Biology, LFNG, Cellular and Molecular Neuroscience, Somitogenesis, Genetics, medicine, Paraxial mesoderm, Pattern Formation, HES1, lcsh:QH301-705.5, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecology, Systems Biology, Computational Biology, Clock and wavefront model, Signaling Networks, Cell biology, medicine.anatomical_structure, lcsh:Biology (General), Computational Theory and Mathematics, Modeling and Simulation, Research Article, Developmental Biology

Abstract

The segmentation of the vertebrate body is laid down during early embryogenesis. The formation of signaling gradients, the periodic expression of genes of the Notch-, Fgf- and Wnt-pathways and their interplay in the unsegmented presomitic mesoderm (PSM) precedes the rhythmic budding of nascent somites at its anterior end, which later develops into epithelialized structures, the somites. Although many in silico models describing partial aspects of somitogenesis already exist, simulations of a complete causal chain from gene expression in the growth zone via the interaction of multiple cells to segmentation are rare. Here, we present an enhanced gene regulatory network (GRN) for mice in a simulation program that models the growing PSM by many virtual cells and integrates WNT3A and FGF8 gradient formation, periodic gene expression and Delta/Notch signaling. Assuming Hes7 as core of the somitogenesis clock and LFNG as modulator, we postulate a negative feedback of HES7 on Dll1 leading to an oscillating Dll1 expression as seen in vivo. Furthermore, we are able to simulate the experimentally observed wave of activated NOTCH (NICD) as a result of the interactions in the GRN. We esteem our model as robust for a wide range of parameter values with the Hes7 mRNA and protein decays exerting a strong influence on the core oscillator. Moreover, our model predicts interference between Hes1 and HES7 oscillators when their intrinsic frequencies differ. In conclusion, we have built a comprehensive model of somitogenesis with HES7 as core oscillator that is able to reproduce many experimentally observed data in mice., Author Summary Somitogenesis is a process in embryonic development establishing the segmentation of the vertebrate body by the periodic separation of small balls of epithelialized cells called somites from a growing mesenchymal tissue, the presomitic mesoderm (PSM). The basic mechanisms are often discussed in terms of the clock-and-wave-front model, which was proposed already in 1976. Candidate genes for this model were found only in the last fifteen years with the cyclically expressed Hairy/Hes genes functioning as the clock and posteriorly expressed Fgf, Tbx6, and Wnt genes establishing the gradient(s). In addition, the Delta/Notch signal transduction pathway seems to be important for boundary formation between forming somites and the remaining PSM by inducing Mesp2 expression just behind a future somitic boundary. Although many in silico models describing partial aspects of somitogenesis already exist, there are still conflicts regarding the mechanisms of the somitogenesis clock. Furthermore, a simulation that fully integrates clock and gradient was only recently published for chicken. Here, we propose a cell- and gene-based computer model for mammalian somitogenesis, simulating a gene regulatory network combining clock (Hes1/7) and gradient (Tbx6, Fgf8, Wnt3a) with Delta/Notch signaling resulting in dynamic gene expression patterns as observed in vivo finally leading to boundary formation.

Published

2012