26 results on '"Kaucka M"'
Search Results
2. Striking parallels between carotid body glomus cell and adrenal chromaffin cell development
- Author
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Hockman, D, Adameyko, I, Kaucka, M, Barraud, P, Otani, T, Hunt, A, Hartwig, A, Sock, E, Waithe, D, Franck, M, Ernfors, P, Ehinger, S, Howard, M, Brown, N, Reese, J, Baker, C, Baker, Clare [0000-0002-4434-3107], and Apollo - University of Cambridge Repository
- Subjects
Mice, Knockout ,Neurons ,Carotid Body ,Carotid body glomus cells ,Chromaffin Cells ,Neurosciences ,Cell Differentiation ,Chick Embryo ,Cell Hypoxia ,Article ,Mice ,Neural crest ,Nodose neurons ,Adrenal Glands ,Basic Helix-Loop-Helix Transcription Factors ,Animals ,Adrenal chromaffin cells ,Myelin Proteolipid Protein ,Pericytes ,Chickens ,Neurovetenskaper ,Body Patterning ,Transcription Factors ,Schwann cell precursors - Abstract
Carotid body glomus cells mediate essential reflex responses to arterial blood hypoxia. They are dopaminergic and secrete growth factors that support dopaminergic neurons, making the carotid body a potential source of patient-specific cells for Parkinson's disease therapy. Like adrenal chromaffin cells, which are also hypoxia-sensitive, glomus cells are neural crest-derived and require the transcription factors Ascl1 and Phox2b; otherwise, their development is little understood at the molecular level. Here, analysis in chicken and mouse reveals further striking molecular parallels, though also some differences, between glomus and adrenal chromaffin cell development. Moreover, histology has long suggested that glomus cell precursors are ‘émigrés’ from neighbouring ganglia/nerves, while multipotent nerve-associated glial cells are now known to make a significant contribution to the adrenal chromaffin cell population in the mouse. We present conditional genetic lineage-tracing data from mice supporting the hypothesis that progenitors expressing the glial marker proteolipid protein 1, presumably located in adjacent ganglia/nerves, also contribute to glomus cells. Finally, we resolve a paradox for the ‘émigré’ hypothesis in the chicken - where the nearest ganglion to the carotid body is the nodose, in which the satellite glia are neural crest-derived, but the neurons are almost entirely placode-derived - by fate-mapping putative nodose neuronal 'émigrés' to the neural crest., Highlights • Glomus cell precursors express the neuron-specific marker Elavl3/4 (HuC/D). • Developing glomus cells express multiple ‘sympathoadrenal' genes. • Glomus cell development requires Hand2 and Sox4/11, but not Ret or Tfap2b. • Multipotent progenitors with a glial phenotype contribute to glomus cells. • Fate-mapping resolves a paradox for the ganglionic 'émigré' hypothesis in birds.
- Published
- 2018
3. Analysis of neural crest–derived clones reveals novel aspects of facial development
- Author
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Kaucka, M, Ivashkin, E, Gyllborg, D, Zikmund, T, Tesarova, M, Kaiser, J, Xie, M, Petersen, J, Pachnis, V, Nicolis, S, Yu, T, Sharpe, P, Arenas, E, Brismar, H, Blom, H, Clevers, H, Suter, U, Chagin, A, Fried, K, Hellander, A, Adameyko, I, Adameyko, I., NICOLIS, SILVIA KIRSTEN, Kaucka, M, Ivashkin, E, Gyllborg, D, Zikmund, T, Tesarova, M, Kaiser, J, Xie, M, Petersen, J, Pachnis, V, Nicolis, S, Yu, T, Sharpe, P, Arenas, E, Brismar, H, Blom, H, Clevers, H, Suter, U, Chagin, A, Fried, K, Hellander, A, Adameyko, I, Adameyko, I., and NICOLIS, SILVIA KIRSTEN
- Abstract
Cranial neural crest cells populate the future facial region and produce ectomesenchyme-derived tissues, such as cartilage, bone, dermis, smooth muscle, adipocytes, and many others. However, the contribution of individual neural crest cells to certain facial locations and the general spatial clonal organization of the ectomesenchyme have not been determined. We investigated how neural crest cells give rise to clonally organized ectomesenchyme and how this early ectomesenchyme behaves during the developmental processes that shape the face. Using a combination of mouse and zebrafish models, we analyzed individual migration, cell crowd movement, oriented cell division, clonal spatial overlapping, and multilineage differentiation. The early face appears to be built from multiple spatially defined overlapping ectomesenchymal clones. During early face development, these clones remain oligopotent and generate various tissues in a given location. By combining clonal analysis, computer simulations, mouse mutants, and live imaging, we show that facial shaping results from an array of local cellular activities in the ectomesenchyme. These activities mostly involve oriented divisions and crowd movements of cells during morphogenetic events. Cellular behavior that can be recognized as individual cell migration is very limited and short-ranged and likely results from cellular mixing due to the proliferation activity of the tissue. These cellular mechanisms resemble the strategy behind limb bud morphogenesis, suggesting the possibility of common principles and deep homology between facial and limb outgrowth.
- Published
- 2016
4. Spatiotemporal structure of cell fate decisions in murine neural crest
- Author
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Maria Eleni Kastriti, David A. Guertin, G. Giacomo Consalez, Julian Petersen, Ruslan A. Soldatov, Xiaoyan Qian, Yunshi Yang, Tatiana Chontorotzea, Wen Yu Hsiao, Michael L. Piacentino, Markus M. Hilscher, Jean-François Brunet, Matthias Farlik, Viacheslav Dyachuk, Marketa Kaucka, Kaj Fried, Martin Häring, Chika Yokota, Mats Nilsson, Peter V. Kharchenko, Lukas Englmaier, Christoph Bock, Laura Croci, Igor Adameyko, Marianne E. Bronner, Franck Boismoreau, Patrik Ernfors, Natalia Akkuratova, Soldatov, R, Kaucka, M, Kastriti, Me, Petersen, J, Chontorotzea, T, Englmaier, L, Akkuratova, N, Yang, Y, Häring, M, Dyachuk, V, Bock, C, Farlik, M, Piacentino, Ml, Boismoreau, F, Hilscher, Mm, Yokota, C, Qian, X, Nilsson, M, Bronner, M, Croci, L, Hsiao, Wy, Guertin, D, Brunet, Jf, Consalez, Gg, Ernfors, P, Fried, K, Kharchenko, Pv, and Adameyko, I
- Subjects
0301 basic medicine ,Cell type ,Neural Tube ,Ectomesenchyme ,Neurogenesis ,Nerve Tissue Proteins ,Biology ,Cell fate determination ,03 medical and health sciences ,Mice ,0302 clinical medicine ,Cranial neural crest ,Single-cell analysis ,Neural Stem Cells ,medicine ,Basic Helix-Loop-Helix Transcription Factors ,Animals ,Cell Lineage ,Neurons ,Multidisciplinary ,Twist-Related Protein 1 ,Neural tube ,Neural crest ,Gene Expression Regulation, Developmental ,Nuclear Proteins ,Mesenchymal Stem Cells ,Embryonic stem cell ,Mice, Mutant Strains ,030104 developmental biology ,medicine.anatomical_structure ,Neural Crest ,Single-Cell Analysis ,Neuroscience ,Neuroglia ,030217 neurology & neurosurgery - Abstract
Binary decisions refine fate decisions Neural crest cells develop into tissues ranging from craniofacial bones to peripheral neurons. Combining single-cell RNA sequencing with spatial transcriptomics, Soldatov et al. analyzed how neural crest cells in mouse embryos decide among the various fates available to them (see the Perspective by Mayor). These multipotent cells become biased toward a given fate early on and step through a progression of binary decisions as their fate is refined. Competing fate programs coexist until increased synchronization favors one and repression disfavors the other. Science , this issue p. eaas9536 ; see also p. 937
- Published
- 2019
5. Analysis of neural crest-derived clones reveals novel aspects of facial development
- Author
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Kaj Fried, Hans Clevers, Tian Yu, Andrei S. Chagin, Tomáš Zikmund, Silvia K. Nicolis, Vassilis Pachnis, Ueli Suter, Meng Xie, Hjalmar Brismar, Jozef Kaiser, Ernest Arenas, Hans Blom, Marketa Kaucka, Paul T. Sharpe, Andreas Hellander, Daniel Gyllborg, Igor Adameyko, Marketa Tesarova, Julian Petersen, E. G. Ivashkin, Hubrecht Institute for Developmental Biology and Stem Cell Research, Kaucka, M, Ivashkin, E, Gyllborg, D, Zikmund, T, Tesarova, M, Kaiser, J, Xie, M, Petersen, J, Pachnis, V, Nicolis, S, Yu, T, Sharpe, P, Arenas, E, Brismar, H, Blom, H, Clevers, H, Suter, U, Chagin, A, Fried, K, Hellander, A, and Adameyko, I
- Subjects
Models, Anatomic ,0301 basic medicine ,Early face development ,genetic structures ,morphogenesi ,analysis ,Organogenesis ,Cellular differentiation ,Gene Expression ,Ectoderm ,migration ,Mesoderm ,Mice ,Cranial neural crest ,Cell Movement ,Genes, Reporter ,Morphogenesis ,Non-U.S. Gov't ,Zebrafish ,Research Articles ,neural crest cells ,Medicine(all) ,Multidisciplinary ,biology ,Research Support, Non-U.S. Gov't ,SciAdv r-articles ,Life Sciences ,Neural crest ,Cell Differentiation ,Anatomy ,embryonic development ,clonal envelopes ,morphogenesis ,Phenotype ,medicine.anatomical_structure ,Neural Crest ,Research Article ,Ectomesenchyme ,ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION ,Research Support ,facial development ,N.I.H ,03 medical and health sciences ,Imaging, Three-Dimensional ,Research Support, N.I.H., Extramural ,medicine ,Journal Article ,Animals ,ComputingMethodologies_COMPUTERGRAPHICS ,clonal envelope ,Extramural ,biology.organism_classification ,Clone Cells ,stomatognathic diseases ,030104 developmental biology ,Face ,Neuroscience - Abstract
Cranial neural crest cells populate the future facial region and produce ectomesenchyme-derived tissues, such as cartilage, bone, dermis, smooth muscle, adipocytes, and many others. However, the contribution of individual neural crest cells to certain facial locations and the general spatial clonal organization of the ectomesenchyme have not been determined. We investigated how neural crest cells give rise to clonally organized ectomesenchyme and how this early ectomesenchyme behaves during the developmental processes that shape the face. Using a combination of mouse and zebrafish models, we analyzed individual migration, cell crowd movement, oriented cell division, clonal spatial overlapping, and multilineage differentiation. The early face appears to be built from multiple spatially defined overlapping ectomesenchymal clones. During early face development, these clones remain oligopotent and generate various tissues in a given location. By combining clonal analysis, computer simulations, mouse mutants, and live imaging, we show that facial shaping results from an array of local cellular activities in the ectomesenchyme. These activities mostly involve oriented divisions and crowd movements of cells during morphogenetic events. Cellular behavior that can be recognized as individual cell migration is very limited and short-ranged and likely results from cellular mixing due to the proliferation activity of the tissue. These cellular mechanisms resemble the strategy behind limb bud morphogenesis, suggesting the possibility of common principles and deep homology between facial and limb outgrowth., Science Advances, 2 (8), ISSN:2375-2548
- Published
- 2016
6. Cis -regulatory landscapes in the evolution and development of the mammalian skull.
- Author
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Kaucka M
- Subjects
- Animals, Gene Regulatory Networks, Skull, Head, Evolution, Molecular, Mammals genetics
- Abstract
Extensive morphological variation found in mammals reflects the wide spectrum of their ecological adaptations. The highest morphological diversity is present in the craniofacial region, where geometry is mainly dictated by the bony skull. Mammalian craniofacial development represents complex multistep processes governed by numerous conserved genes that require precise spatio-temporal control. A central question in contemporary evolutionary biology is how a defined set of conserved genes can orchestrate formation of fundamentally different structures, and therefore how morphological variability arises. In principle, differential gene expression patterns during development are the source of morphological variation. With the emergence of multicellular organisms, precise regulation of gene expression in time and space is attributed to cis -regulatory elements. These elements contribute to higher-order chromatin structure and together with trans -acting factors control transcriptional landscapes that underlie intricate morphogenetic processes. Consequently, divergence in cis -regulation is believed to rewire existing gene regulatory networks and form the core of morphological evolution. This review outlines the fundamental principles of the genetic code and genomic regulation interplay during development. Recent work that deepened our comprehension of cis -regulatory element origin, divergence and function is presented here to illustrate the state-of-the-art research that uncovered the principles of morphological novelty. This article is part of the theme issue 'The mammalian skull: development, structure and function'.
- Published
- 2023
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7. Author Correction: A previously uncharacterized Factor Associated with Metabolism and Energy (FAME/C14orf105/CCDC198/1700011H14Rik) is related to evolutionary adaptation, energy balance, and kidney physiology.
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Petersen J, Englmaier L, Artemov AV, Poverennaya I, Mahmoud R, Bouderlique T, Tesarova M, Deviatiiarov R, Szilvásy-Szabó A, Akkuratov EE, Pajuelo Reguera D, Zeberg H, Kaucka M, Kastriti ME, Krivanek J, Radaszkiewicz T, Gömöryová K, Knauth S, Potesil D, Zdrahal Z, Ganji RS, Grabowski A, Buhl ME, Zikmund T, Kavkova M, Axelson H, Lindgren D, Kramann R, Kuppe C, Erdélyi F, Máté Z, Szabó G, Koehne T, Harkany T, Fried K, Kaiser J, Boor P, Fekete C, Rozman J, Kasparek P, Prochazka J, Sedlacek R, Bryja V, Gusev O, and Adameyko I
- Published
- 2023
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8. A previously uncharacterized Factor Associated with Metabolism and Energy (FAME/C14orf105/CCDC198/1700011H14Rik) is related to evolutionary adaptation, energy balance, and kidney physiology.
- Author
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Petersen J, Englmaier L, Artemov AV, Poverennaya I, Mahmoud R, Bouderlique T, Tesarova M, Deviatiiarov R, Szilvásy-Szabó A, Akkuratov EE, Pajuelo Reguera D, Zeberg H, Kaucka M, Kastriti ME, Krivanek J, Radaszkiewicz T, Gömöryová K, Knauth S, Potesil D, Zdrahal Z, Ganji RS, Grabowski A, Buhl ME, Zikmund T, Kavkova M, Axelson H, Lindgren D, Kramann R, Kuppe C, Erdélyi F, Máté Z, Szabó G, Koehne T, Harkany T, Fried K, Kaiser J, Boor P, Fekete C, Rozman J, Kasparek P, Prochazka J, Sedlacek R, Bryja V, Gusev O, and Adameyko I
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- Animals, Humans, Body Weight, Ferritins genetics, Kidney, Neanderthals, Energy Metabolism genetics, Genome-Wide Association Study
- Abstract
In this study we use comparative genomics to uncover a gene with uncharacterized function (1700011H14Rik/C14orf105/CCDC198), which we hereby name FAME (Factor Associated with Metabolism and Energy). We observe that FAME shows an unusually high evolutionary divergence in birds and mammals. Through the comparison of single nucleotide polymorphisms, we identify gene flow of FAME from Neandertals into modern humans. We conduct knockout experiments on animals and observe altered body weight and decreased energy expenditure in Fame knockout animals, corresponding to genome-wide association studies linking FAME with higher body mass index in humans. Gene expression and subcellular localization analyses reveal that FAME is a membrane-bound protein enriched in the kidneys. Although the gene knockout results in structurally normal kidneys, we detect higher albumin in urine and lowered ferritin in the blood. Through experimental validation, we confirm interactions between FAME and ferritin and show co-localization in vesicular and plasma membranes., (© 2023. The Author(s).)
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- 2023
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9. Directionality of developing skeletal muscles is set by mechanical forces.
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Sunadome K, Erickson AG, Kah D, Fabry B, Adori C, Kameneva P, Faure L, Kanatani S, Kaucka M, Dehnisch Ellström I, Tesarova M, Zikmund T, Kaiser J, Edwards S, Maki K, Adachi T, Yamamoto T, Fried K, and Adameyko I
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- Animals, Mice, Myofibrils physiology, Morphogenesis, Myoblasts physiology, Zebrafish genetics, Muscle, Skeletal physiology
- Abstract
Formation of oriented myofibrils is a key event in musculoskeletal development. However, the mechanisms that drive myocyte orientation and fusion to control muscle directionality in adults remain enigmatic. Here, we demonstrate that the developing skeleton instructs the directional outgrowth of skeletal muscle and other soft tissues during limb and facial morphogenesis in zebrafish and mouse. Time-lapse live imaging reveals that during early craniofacial development, myoblasts condense into round clusters corresponding to future muscle groups. These clusters undergo oriented stretch and alignment during embryonic growth. Genetic perturbation of cartilage patterning or size disrupts the directionality and number of myofibrils in vivo. Laser ablation of musculoskeletal attachment points reveals tension imposed by cartilage expansion on the forming myofibers. Application of continuous tension using artificial attachment points, or stretchable membrane substrates, is sufficient to drive polarization of myocyte populations in vitro. Overall, this work outlines a biomechanical guidance mechanism that is potentially useful for engineering functional skeletal muscle., (© 2023. The Author(s).)
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- 2023
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10. Altered developmental programs and oriented cell divisions lead to bulky bones during salamander limb regeneration.
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Kaucka M, Joven Araus A, Tesarova M, Currie JD, Boström J, Kavkova M, Petersen J, Yao Z, Bouchnita A, Hellander A, Zikmund T, Elewa A, Newton PT, Fei JF, Chagin AS, Fried K, Tanaka EM, Kaiser J, Simon A, and Adameyko I
- Subjects
- Animals, Bone and Bones, Cartilage, Cell Division, Mammals, Urodela, Osteogenesis
- Abstract
There are major differences in duration and scale at which limb development and regeneration proceed, raising the question to what extent regeneration is a recapitulation of development. We address this by analyzing skeletal elements using a combination of micro-CT imaging, molecular profiling and clonal cell tracing. We find that, in contrast to development, regenerative skeletal growth is accomplished based entirely on cartilage expansion prior to ossification, not limiting the transversal cartilage expansion and resulting in bulkier skeletal parts. The oriented extension of salamander cartilage and bone appear similar to the development of basicranial synchondroses in mammals, as we found no evidence for cartilage stem cell niches or growth plate-like structures during neither development nor regeneration. Both regenerative and developmental ossification in salamanders start from the cortical bone and proceeds inwards, showing the diversity of schemes for the synchrony of cortical and endochondral ossification among vertebrates., (© 2022. The Author(s).)
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- 2022
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11. Schwann cell precursors represent a neural crest-like state with biased multipotency.
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Kastriti ME, Faure L, Von Ahsen D, Bouderlique TG, Boström J, Solovieva T, Jackson C, Bronner M, Meijer D, Hadjab S, Lallemend F, Erickson A, Kaucka M, Dyachuk V, Perlmann T, Lahti L, Krivanek J, Brunet JF, Fried K, and Adameyko I
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- Cell Differentiation physiology, Neurogenesis physiology, Peripheral Nerves, Neural Crest, Schwann Cells metabolism
- Abstract
Schwann cell precursors (SCPs) are nerve-associated progenitors that can generate myelinating and non-myelinating Schwann cells but also are multipotent like the neural crest cells from which they originate. SCPs are omnipresent along outgrowing peripheral nerves throughout the body of vertebrate embryos. By using single-cell transcriptomics to generate a gene expression atlas of the entire neural crest lineage, we show that early SCPs and late migratory crest cells have similar transcriptional profiles characterised by a multipotent "hub" state containing cells biased towards traditional neural crest fates. SCPs keep diverging from the neural crest after being primed towards terminal Schwann cells and other fates, with different subtypes residing in distinct anatomical locations. Functional experiments using CRISPR-Cas9 loss-of-function further show that knockout of the common "hub" gene Sox8 causes defects in neural crest-derived cells along peripheral nerves by facilitating differentiation of SCPs towards sympathoadrenal fates. Finally, specific tumour populations found in melanoma, neurofibroma and neuroblastoma map to different stages of SCP/Schwann cell development. Overall, SCPs resemble migrating neural crest cells that maintain multipotency and become transcriptionally primed towards distinct lineages., (©2022 The Authors. Published under the terms of the CC BY 4.0 license.)
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- 2022
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12. Resolving complex cartilage structures in developmental biology via deep learning-based automatic segmentation of X-ray computed microtomography images.
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Matula J, Polakova V, Salplachta J, Tesarova M, Zikmund T, Kaucka M, Adameyko I, and Kaiser J
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- Animals, Cartilage diagnostic imaging, Developmental Biology, Image Processing, Computer-Assisted methods, Mice, Neural Networks, Computer, X-Rays, Deep Learning
- Abstract
The complex shape of embryonic cartilage represents a true challenge for phenotyping and basic understanding of skeletal development. X-ray computed microtomography (μCT) enables inspecting relevant tissues in all three dimensions; however, most 3D models are still created by manual segmentation, which is a time-consuming and tedious task. In this work, we utilised a convolutional neural network (CNN) to automatically segment the most complex cartilaginous system represented by the developing nasal capsule. The main challenges of this task stem from the large size of the image data (over a thousand pixels in each dimension) and a relatively small training database, including genetically modified mouse embryos, where the phenotype of the analysed structures differs from the norm. We propose a CNN-based segmentation model optimised for the large image size that we trained using a unique manually annotated database. The segmentation model was able to segment the cartilaginous nasal capsule with a median accuracy of 84.44% (Dice coefficient). The time necessary for segmentation of new samples shortened from approximately 8 h needed for manual segmentation to mere 130 s per sample. This will greatly accelerate the throughput of μCT analysis of cartilaginous skeletal elements in animal models of developmental diseases., (© 2022. The Author(s).)
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- 2022
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13. Nerve-associated Schwann cell precursors contribute extracutaneous melanocytes to the heart, inner ear, supraorbital locations and brain meninges.
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Kaucka M, Szarowska B, Kavkova M, Kastriti ME, Kameneva P, Schmidt I, Peskova L, Joven Araus A, Simon A, Kaiser J, and Adameyko I
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- Amphibians metabolism, Amphibians physiology, Animals, Brain metabolism, Cell Lineage physiology, Ear, Inner metabolism, Embryonic Development physiology, Female, Fishes metabolism, Fishes physiology, Melanocytes metabolism, Melanocytes physiology, Meninges metabolism, Mice, Nervous System metabolism, Pregnancy, Receptor, Endothelin B metabolism, Schwann Cells metabolism, Brain physiology, Ear, Inner physiology, Heart physiology, Meninges physiology, Nervous System physiopathology, Schwann Cells physiology
- Abstract
Melanocytes are pigmented cells residing mostly in the skin and hair follicles of vertebrates, where they contribute to colouration and protection against UV-B radiation. However, the spectrum of their functions reaches far beyond that. For instance, these pigment-producing cells are found inside the inner ear, where they contribute to the hearing function, and in the heart, where they are involved in the electrical conductivity and support the stiffness of cardiac valves. The embryonic origin of such extracutaneous melanocytes is not clear. We took advantage of lineage-tracing experiments combined with 3D visualizations and gene knockout strategies to address this long-standing question. We revealed that Schwann cell precursors are recruited from the local innervation during embryonic development and give rise to extracutaneous melanocytes in the heart, brain meninges, inner ear, and other locations. In embryos with a knockout of the EdnrB receptor, a condition imitating Waardenburg syndrome, we observed only nerve-associated melanoblasts, which failed to detach from the nerves and to enter the inner ear. Finally, we looked into the evolutionary aspects of extracutaneous melanocytes and found that pigment cells are associated mainly with nerves and blood vessels in amphibians and fish. This new knowledge of the nerve-dependent origin of extracutaneous pigment cells might be directly relevant to the formation of extracutaneous melanoma in humans., (© 2021. The Author(s).)
- Published
- 2021
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14. X-ray microtomography-based atlas of mouse cranial development.
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Matula J, Tesarova M, Zikmund T, Kaucka M, Adameyko I, and Kaiser J
- Subjects
- Animals, Mice, X-Ray Microtomography, Imaging, Three-Dimensional, Skull diagnostic imaging
- Abstract
Background: X-ray microtomography (μCT) has become an invaluable tool for non-destructive analysis of biological samples in the field of developmental biology. Mouse embryos are a typical model for investigation of human developmental diseases. By obtaining 3D high-resolution scans of the mouse embryo heads, we gain valuable morphological information about the structures prominent in the development of future face, brain, and sensory organs. The development of facial skeleton tracked in these μCT data provides a valuable background for further studies of congenital craniofacial diseases and normal development., Findings: In this work, reusable tomographic data from 7 full 3D scans of mouse embryo heads are presented and made publicly available. The ages of these embryos range from E12.5 to E18.5. The samples were stained by phosphotungstic acid prior to scanning, which greatly enhanced the contrast of various tissues in the reconstructed images and enabled precise segmentation. The images were obtained on a laboratory-based μCT system. Furthermore, we provide manually segmented masks of mesenchymal condensations (for E12.5 and E13.5) and cartilage present in the nasal capsule of the scanned embryos., Conclusion: We present a comprehensive dataset of X-ray 3D computed tomography images of the developing mouse head with high-quality manual segmentation masks of cartilaginous nasal capsules. The provided μCT images can be used for studying any other major structure within the developing mouse heads. The high quality of the manually segmented models of nasal capsules may be instrumental to understanding the complex process of the development of the face in a mouse model., (© The Author(s) 2021. Published by Oxford University Press GigaScience.)
- Published
- 2021
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15. Insights Into the Complexity of Craniofacial Development From a Cellular Perspective.
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Murillo-Rincón AP and Kaucka M
- Abstract
The head represents the most complex part of the body and a distinctive feature of the vertebrate body plan. This intricate structure is assembled during embryonic development in the four-dimensional process of morphogenesis. The head integrates components of the central and peripheral nervous system, sensory organs, muscles, joints, glands, and other specialized tissues in the framework of a complexly shaped skull. The anterior part of the head is referred to as the face, and a broad spectrum of facial shapes across vertebrate species enables different feeding strategies, communication styles, and diverse specialized functions. The face formation starts early during embryonic development and is an enormously complex, multi-step process regulated on a genomic, molecular, and cellular level. In this review, we will discuss recent discoveries that revealed new aspects of facial morphogenesis from the time of the neural crest cell emergence till the formation of the chondrocranium, the primary design of the individual facial shape. We will focus on molecular mechanisms of cell fate specification, the role of individual and collective cell migration, the importance of dynamic and continuous cellular interactions, responses of cells and tissues to generated physical forces, and their morphogenetic outcomes. In the end, we will examine the spatiotemporal activity of signaling centers tightly regulating the release of signals inducing the formation of craniofacial skeletal elements. The existence of these centers and their regulation by enhancers represent one of the core morphogenetic mechanisms and might lay the foundations for intra- and inter-species facial variability., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2020 Murillo-Rincón and Kaucka.)
- Published
- 2020
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16. Prototypical pacemaker neurons interact with the resident microbiota.
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Klimovich A, Giacomello S, Björklund Å, Faure L, Kaucka M, Giez C, Murillo-Rincon AP, Matt AS, Willoweit-Ohl D, Crupi G, de Anda J, Wong GCL, D'Amato M, Adameyko I, and Bosch TCG
- Subjects
- Action Potentials, Animals, Biological Evolution, Cluster Analysis, Computational Biology methods, Gene Expression Profiling, Gene Expression Regulation, Genome-Wide Association Study, Humans, Mice, Biological Clocks, Hydra physiology, Microbiota, Neurons physiology
- Abstract
Pacemaker neurons exert control over neuronal circuit function by their intrinsic ability to generate rhythmic bursts of action potential. Recent work has identified rhythmic gut contractions in human, mice, and hydra to be dependent on both neurons and the resident microbiota. However, little is known about the evolutionary origin of these neurons and their interaction with microbes. In this study, we identified and functionally characterized prototypical ANO/SCN/TRPM ion channel-expressing pacemaker cells in the basal metazoan Hydra by using a combination of single-cell transcriptomics, immunochemistry, and functional experiments. Unexpectedly, these prototypical pacemaker neurons express a rich set of immune-related genes mediating their interaction with the microbial environment. Furthermore, functional experiments gave a strong support to a model of the evolutionary emergence of pacemaker cells as neurons using components of innate immunity to interact with the microbial environment and ion channels to generate rhythmic contractions., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)
- Published
- 2020
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17. Differentiation of neural rosettes from human pluripotent stem cells in vitro is sequentially regulated on a molecular level and accomplished by the mechanism reminiscent of secondary neurulation.
- Author
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Fedorova V, Vanova T, Elrefae L, Pospisil J, Petrasova M, Kolajova V, Hudacova Z, Baniariova J, Barak M, Peskova L, Barta T, Kaucka M, Killinger M, Vecera J, Bernatik O, Cajanek L, Hribkova H, and Bohaciakova D
- Subjects
- COUP Transcription Factor II genetics, COUP Transcription Factor II metabolism, Cells, Cultured, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Humans, Neural Stem Cells metabolism, Neural Tube cytology, Neural Tube metabolism, PAX6 Transcription Factor genetics, PAX6 Transcription Factor metabolism, POU Domain Factors genetics, POU Domain Factors metabolism, Pluripotent Stem Cells metabolism, Cell Differentiation, Neural Stem Cells cytology, Neural Tube embryology, Neurulation, Pluripotent Stem Cells cytology
- Abstract
Development of neural tube has been extensively modeled in vitro using human pluripotent stem cells (hPSCs) that are able to form radially organized cellular structures called neural rosettes. While a great amount of research has been done using neural rosettes, studies have only inadequately addressed how rosettes are formed and what the molecular mechanisms and pathways involved in their formation are. Here we address this question by detailed analysis of the expression of pluripotency and differentiation-associated proteins during the early onset of differentiation of hPSCs towards neural rosettes. Additionally, we show that the BMP signaling is likely contributing to the formation of the complex cluster of neural rosettes and its inhibition leads to the altered expression of PAX6, SOX2 and SOX1 proteins and the rosette morphology. Finally, we provide evidence that the mechanism of neural rosettes formation in vitro is reminiscent of the process of secondary neurulation rather than that of primary neurulation in vivo. Since secondary neurulation is a largely unexplored process, its understanding will ultimately assist the development of methods to prevent caudal neural tube defects in humans., (Copyright © 2019. Published by Elsevier B.V.)
- Published
- 2019
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18. Schwann cell precursors contribute to skeletal formation during embryonic development in mice and zebrafish.
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Xie M, Kamenev D, Kaucka M, Kastriti ME, Zhou B, Artemov AV, Storer M, Fried K, Adameyko I, Dyachuk V, and Chagin AS
- Subjects
- Animals, Biomarkers metabolism, Bone and Bones embryology, Bone and Bones metabolism, Cell Differentiation, Chondrocytes metabolism, Chromaffin Cells cytology, Chromaffin Cells metabolism, Embryo, Mammalian, Embryo, Nonmammalian, Embryonic Development, Gene Expression, Melanocytes cytology, Melanocytes metabolism, Mesenchymal Stem Cells metabolism, Mice, Multipotent Stem Cells cytology, Multipotent Stem Cells metabolism, Myelin Proteolipid Protein genetics, Myelin Proteolipid Protein metabolism, Nerve Fibers metabolism, Nerve Tissue embryology, Nerve Tissue metabolism, Neural Crest cytology, Neural Crest growth & development, Neural Crest metabolism, Neural Stem Cells cytology, Neural Stem Cells metabolism, Neuroglia cytology, Neuroglia metabolism, Neurons cytology, Neurons metabolism, Osteocytes cytology, Osteocytes metabolism, SOXE Transcription Factors genetics, SOXE Transcription Factors metabolism, Schwann Cells metabolism, Zebrafish embryology, Zebrafish genetics, Zebrafish metabolism, Bone and Bones cytology, Cell Lineage genetics, Chondrocytes cytology, Mesenchymal Stem Cells cytology, Nerve Tissue cytology, Schwann Cells cytology
- Abstract
Immature multipotent embryonic peripheral glial cells, the Schwann cell precursors (SCPs), differentiate into melanocytes, parasympathetic neurons, chromaffin cells, and dental mesenchymal populations. Here, genetic lineage tracing revealed that, during murine embryonic development, some SCPs detach from nerve fibers to become mesenchymal cells, which differentiate further into chondrocytes and mature osteocytes. This occurred only during embryonic development, producing numerous craniofacial and trunk skeletal elements, without contributing to development of the appendicular skeleton. Formation of chondrocytes from SCPs also occurred in zebrafish, indicating evolutionary conservation. Our findings reveal multipotency of SCPs, providing a developmental link between the nervous system and skeleton., Competing Interests: The authors declare no conflict of interest., (Copyright © 2019 the Author(s). Published by PNAS.)
- Published
- 2019
- Full Text
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19. Striking parallels between carotid body glomus cell and adrenal chromaffin cell development.
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Hockman D, Adameyko I, Kaucka M, Barraud P, Otani T, Hunt A, Hartwig AC, Sock E, Waithe D, Franck MCM, Ernfors P, Ehinger S, Howard MJ, Brown N, Reese J, and Baker CVH
- Subjects
- Adrenal Glands metabolism, Adrenal Glands physiology, Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Body Patterning physiology, Cell Differentiation, Cell Hypoxia physiology, Chick Embryo, Chickens metabolism, Mice, Mice, Knockout, Myelin Proteolipid Protein physiology, Neural Crest metabolism, Neurons metabolism, Pericytes physiology, Transcription Factors metabolism, Carotid Body embryology, Chromaffin Cells metabolism, Pericytes metabolism
- Abstract
Carotid body glomus cells mediate essential reflex responses to arterial blood hypoxia. They are dopaminergic and secrete growth factors that support dopaminergic neurons, making the carotid body a potential source of patient-specific cells for Parkinson's disease therapy. Like adrenal chromaffin cells, which are also hypoxia-sensitive, glomus cells are neural crest-derived and require the transcription factors Ascl1 and Phox2b; otherwise, their development is little understood at the molecular level. Here, analysis in chicken and mouse reveals further striking molecular parallels, though also some differences, between glomus and adrenal chromaffin cell development. Moreover, histology has long suggested that glomus cell precursors are 'émigrés' from neighbouring ganglia/nerves, while multipotent nerve-associated glial cells are now known to make a significant contribution to the adrenal chromaffin cell population in the mouse. We present conditional genetic lineage-tracing data from mice supporting the hypothesis that progenitors expressing the glial marker proteolipid protein 1, presumably located in adjacent ganglia/nerves, also contribute to glomus cells. Finally, we resolve a paradox for the 'émigré' hypothesis in the chicken - where the nearest ganglion to the carotid body is the nodose, in which the satellite glia are neural crest-derived, but the neurons are almost entirely placode-derived - by fate-mapping putative nodose neuronal 'émigrés' to the neural crest., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)
- Published
- 2018
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20. Signals from the brain and olfactory epithelium control shaping of the mammalian nasal capsule cartilage.
- Author
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Kaucka M, Petersen J, Tesarova M, Szarowska B, Kastriti ME, Xie M, Kicheva A, Annusver K, Kasper M, Symmons O, Pan L, Spitz F, Kaiser J, Hovorakova M, Zikmund T, Sunadome K, Matise MP, Wang H, Marklund U, Abdo H, Ernfors P, Maire P, Wurmser M, Chagin AS, Fried K, and Adameyko I
- Subjects
- Animals, Brain drug effects, Brain growth & development, Chondrocytes cytology, Chondrocytes drug effects, Collagen Type II genetics, Collagen Type II metabolism, Embryo, Mammalian, Face anatomy & histology, Face embryology, Facial Bones cytology, Facial Bones drug effects, Facial Bones growth & development, Facial Bones metabolism, Gene Expression Regulation, Developmental, Hedgehog Proteins metabolism, Homeobox Protein Nkx-2.2, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Humans, Integrases genetics, Integrases metabolism, Mice, Mice, Transgenic, Morphogenesis drug effects, Mutagens administration & dosage, Nasal Cartilages cytology, Nasal Cartilages drug effects, Nasal Cartilages growth & development, Nasal Cartilages metabolism, Olfactory Mucosa cytology, Olfactory Mucosa drug effects, Olfactory Mucosa growth & development, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Tamoxifen administration & dosage, Transcription Factors genetics, Transcription Factors metabolism, Zebrafish Proteins, Brain metabolism, Chondrocytes metabolism, Hedgehog Proteins genetics, Maxillofacial Development genetics, Morphogenesis genetics, Olfactory Mucosa metabolism, Signal Transduction
- Abstract
Facial shape is the basis for facial recognition and categorization. Facial features reflect the underlying geometry of the skeletal structures. Here, we reveal that cartilaginous nasal capsule (corresponding to upper jaw and face) is shaped by signals generated by neural structures: brain and olfactory epithelium. Brain-derived Sonic Hedgehog (SHH) enables the induction of nasal septum and posterior nasal capsule, whereas the formation of a capsule roof is controlled by signals from the olfactory epithelium. Unexpectedly, the cartilage of the nasal capsule turned out to be important for shaping membranous facial bones during development. This suggests that conserved neurosensory structures could benefit from protection and have evolved signals inducing cranial cartilages encasing them. Experiments with mutant mice revealed that the genomic regulatory regions controlling production of SHH in the nervous system contribute to facial cartilage morphogenesis, which might be a mechanism responsible for the adaptive evolution of animal faces and snouts., Competing Interests: MK, JP, MT, BS, MK, MX, AK, KA, MK, OS, LP, FS, JK, MH, TZ, KS, MM, HW, UM, HA, PE, PM, MW, AC, KF, IA No competing interests declared, (© 2018, Kaucka et al.)
- Published
- 2018
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21. Oriented clonal cell dynamics enables accurate growth and shaping of vertebrate cartilage.
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Kaucka M, Zikmund T, Tesarova M, Gyllborg D, Hellander A, Jaros J, Kaiser J, Petersen J, Szarowska B, Newton PT, Dyachuk V, Li L, Qian H, Johansson AS, Mishina Y, Currie JD, Tanaka EM, Erickson A, Dudley A, Brismar H, Southam P, Coen E, Chen M, Weinstein LS, Hampl A, Arenas E, Chagin AS, Fried K, and Adameyko I
- Subjects
- Animals, Computer Simulation, Mice, Models, Biological, Cartilage embryology, Vertebrates embryology
- Abstract
Cartilaginous structures are at the core of embryo growth and shaping before the bone forms. Here we report a novel principle of vertebrate cartilage growth that is based on introducing transversally-oriented clones into pre-existing cartilage. This mechanism of growth uncouples the lateral expansion of curved cartilaginous sheets from the control of cartilage thickness, a process which might be the evolutionary mechanism underlying adaptations of facial shape. In rod-shaped cartilage structures (Meckel, ribs and skeletal elements in developing limbs), the transverse integration of clonal columns determines the well-defined diameter and resulting rod-like morphology. We were able to alter cartilage shape by experimentally manipulating clonal geometries. Using in silico modeling, we discovered that anisotropic proliferation might explain cartilage bending and groove formation at the macro-scale.
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- 2017
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22. Spotlight on the Schwann cells during the regeneration.
- Author
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Kaucka M and Adameyko I
- Abstract
Competing Interests: The authors have no conflicts of interest to declare.
- Published
- 2016
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23. Analysis of neural crest-derived clones reveals novel aspects of facial development.
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Kaucka M, Ivashkin E, Gyllborg D, Zikmund T, Tesarova M, Kaiser J, Xie M, Petersen J, Pachnis V, Nicolis SK, Yu T, Sharpe P, Arenas E, Brismar H, Blom H, Clevers H, Suter U, Chagin AS, Fried K, Hellander A, and Adameyko I
- Subjects
- Animals, Cell Movement, Ectoderm cytology, Ectoderm embryology, Gene Expression, Genes, Reporter, Imaging, Three-Dimensional, Mesoderm cytology, Mesoderm embryology, Mice, Models, Anatomic, Phenotype, Zebrafish, Cell Differentiation, Clone Cells cytology, Face embryology, Morphogenesis, Neural Crest cytology, Organogenesis
- Abstract
Cranial neural crest cells populate the future facial region and produce ectomesenchyme-derived tissues, such as cartilage, bone, dermis, smooth muscle, adipocytes, and many others. However, the contribution of individual neural crest cells to certain facial locations and the general spatial clonal organization of the ectomesenchyme have not been determined. We investigated how neural crest cells give rise to clonally organized ectomesenchyme and how this early ectomesenchyme behaves during the developmental processes that shape the face. Using a combination of mouse and zebrafish models, we analyzed individual migration, cell crowd movement, oriented cell division, clonal spatial overlapping, and multilineage differentiation. The early face appears to be built from multiple spatially defined overlapping ectomesenchymal clones. During early face development, these clones remain oligopotent and generate various tissues in a given location. By combining clonal analysis, computer simulations, mouse mutants, and live imaging, we show that facial shaping results from an array of local cellular activities in the ectomesenchyme. These activities mostly involve oriented divisions and crowd movements of cells during morphogenetic events. Cellular behavior that can be recognized as individual cell migration is very limited and short-ranged and likely results from cellular mixing due to the proliferation activity of the tissue. These cellular mechanisms resemble the strategy behind limb bud morphogenesis, suggesting the possibility of common principles and deep homology between facial and limb outgrowth.
- Published
- 2016
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24. Autocrine Signaling by Wnt-5a Deregulates Chemotaxis of Leukemic Cells and Predicts Clinical Outcome in Chronic Lymphocytic Leukemia.
- Author
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Janovska P, Poppova L, Plevova K, Plesingerova H, Behal M, Kaucka M, Ovesna P, Hlozkova M, Borsky M, Stehlikova O, Brychtova Y, Doubek M, Machalova M, Baskar S, Kozubik A, Pospisilova S, Pavlova S, and Bryja V
- Subjects
- B-Lymphocytes metabolism, Cell Movement physiology, Gene Expression Regulation, Neoplastic physiology, HEK293 Cells, Humans, Receptor Tyrosine Kinase-like Orphan Receptors metabolism, Up-Regulation physiology, Wnt-5a Protein, Autocrine Communication physiology, Chemotaxis physiology, Leukemia, Lymphocytic, Chronic, B-Cell metabolism, Proto-Oncogene Proteins metabolism, Wnt Proteins metabolism, Wnt Signaling Pathway physiology
- Abstract
Purpose: ROR1, a receptor in the noncanonical Wnt/planar cell polarity (PCP) pathway, is upregulated in malignant B cells of chronic lymphocytic leukemia (CLL) patients. It has been shown that the Wnt/PCP pathway drives pathogenesis of CLL, but which factors activate the ROR1 and PCP pathway in CLL cells remains unclear., Experimental Design: B lymphocytes from the peripheral blood of CLL patients were negatively separated using RosetteSep (StemCell) and gradient density centrifugation. Relative expression of WNT5A, WNT5B, and ROR1 was assessed by quantitative real-time PCR. Protein levels, protein interaction, and downstream signaling were analyzed by immunoprecipitation and Western blotting. Migration capacity of primary CLL cells was analyzed by the Transwell migration assay., Results: By analyzing the expression in 137 previously untreated CLL patients, we demonstrate that WNT5A and WNT5B genes show dramatically (five orders of magnitude) varying expression in CLL cells. High WNT5A and WNT5B expression strongly associates with unmutated IGHV and shortened time to first treatment. In addition, WNT5A levels associate, independent of IGHV status, with the clinically worst CLL subgroups characterized by dysfunctional p53 and mutated SF3B1. We provide functional evidence that WNT5A-positive primary CLL cells have increased motility and attenuated chemotaxis toward CXCL12 and CCL19 that can be overcome by inhibitors of Wnt/PCP signaling., Conclusions: These observations identify Wnt-5a as the crucial regulator of ROR1 activity in CLL and suggest that the autocrine Wnt-5a signaling pathway allows CLL cells to overcome natural microenvironmental regulation., (©2015 American Association for Cancer Research.)
- Published
- 2016
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25. Glial origin of mesenchymal stem cells in a tooth model system.
- Author
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Kaukua N, Shahidi MK, Konstantinidou C, Dyachuk V, Kaucka M, Furlan A, An Z, Wang L, Hultman I, Ahrlund-Richter L, Blom H, Brismar H, Lopes NA, Pachnis V, Suter U, Clevers H, Thesleff I, Sharpe P, Ernfors P, Fried K, and Adameyko I
- Subjects
- Animals, Cell Tracking, Clone Cells cytology, Dental Pulp cytology, Female, Incisor embryology, Male, Mice, Models, Biological, Neural Crest cytology, Odontoblasts cytology, Regeneration, Schwann Cells cytology, Cell Differentiation, Cell Lineage, Incisor cytology, Mesenchymal Stem Cells cytology, Neuroglia cytology
- Abstract
Mesenchymal stem cells occupy niches in stromal tissues where they provide sources of cells for specialized mesenchymal derivatives during growth and repair. The origins of mesenchymal stem cells have been the subject of considerable discussion, and current consensus holds that perivascular cells form mesenchymal stem cells in most tissues. The continuously growing mouse incisor tooth offers an excellent model to address the origin of mesenchymal stem cells. These stem cells dwell in a niche at the tooth apex where they produce a variety of differentiated derivatives. Cells constituting the tooth are mostly derived from two embryonic sources: neural crest ectomesenchyme and ectodermal epithelium. It has been thought for decades that the dental mesenchymal stem cells giving rise to pulp cells and odontoblasts derive from neural crest cells after their migration in the early head and formation of ectomesenchymal tissue. Here we show that a significant population of mesenchymal stem cells during development, self-renewal and repair of a tooth are derived from peripheral nerve-associated glia. Glial cells generate multipotent mesenchymal stem cells that produce pulp cells and odontoblasts. By combining a clonal colour-coding technique with tracing of peripheral glia, we provide new insights into the dynamics of tooth organogenesis and growth.
- Published
- 2014
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26. Receptor tyrosine kinases activate canonical WNT/β-catenin signaling via MAP kinase/LRP6 pathway and direct β-catenin phosphorylation.
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Krejci P, Aklian A, Kaucka M, Sevcikova E, Prochazkova J, Masek JK, Mikolka P, Pospisilova T, Spoustova T, Weis M, Paznekas WA, Wolf JH, Gutkind JS, Wilcox WR, Kozubik A, Jabs EW, Bryja V, Salazar L, Vesela I, and Balek L
- Subjects
- Glycogen Synthase Kinase 3 genetics, Glycogen Synthase Kinase 3 metabolism, HEK293 Cells, Humans, Low Density Lipoprotein Receptor-Related Protein-6 genetics, Low Density Lipoprotein Receptor-Related Protein-6 metabolism, Mitogen-Activated Protein Kinases genetics, Mitogen-Activated Protein Kinases metabolism, Phosphatidylinositol 3-Kinases genetics, Phosphatidylinositol 3-Kinases metabolism, Phosphorylation, Proto-Oncogene Proteins c-akt genetics, Proto-Oncogene Proteins c-akt metabolism, Receptor Protein-Tyrosine Kinases, Wnt Proteins genetics, Wnt Proteins metabolism, beta Catenin genetics, beta Catenin metabolism, Gene Expression Regulation, MAP Kinase Signaling System genetics, Wnt Signaling Pathway genetics
- Abstract
Receptor tyrosine kinase signaling cooperates with WNT/β-catenin signaling in regulating many biological processes, but the mechanisms of their interaction remain poorly defined. We describe a potent activation of WNT/β-catenin by FGFR2, FGFR3, EGFR and TRKA kinases, which is independent of the PI3K/AKT pathway. Instead, this phenotype depends on ERK MAP kinase-mediated phosphorylation of WNT co-receptor LRP6 at Ser1490 and Thr1572 during its Golgi network-based maturation process. This phosphorylation dramatically increases the cellular response to WNT. Moreover, FGFR2, FGFR3, EGFR and TRKA directly phosphorylate β-catenin at Tyr142, which is known to increase cytoplasmic β-catenin concentration via release of β-catenin from membranous cadherin complexes. We conclude that signaling via ERK/LRP6 pathway and direct β-catenin phosphorylation at Tyr142 represent two mechanisms used by various receptor tyrosine kinase systems to activate canonical WNT signaling.
- Published
- 2012
- Full Text
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