fbpx
Wikipedia

Morphogenesis

February 15, 2024

This article is about the biological process. For other uses, see Morphogenesis (disambiguation).

Morphogenesis (from the Greek morphê shape and genesis creation, literally "the generation of form") is the biological process that causes a cell, tissue or organism to develop its shape. It is one of three fundamental aspects of developmental biology along with the control of tissue growth and patterning of cellular differentiation.

The process controls the organized spatial distribution of cells during the embryonic development of an organism. Morphogenesis can take place also in a mature organism, such as in the normal maintenance of tissue by stem cells or in regeneration of tissues after damage. Cancer is an example of highly abnormal and pathological tissue morphogenesis. Morphogenesis also describes the development of unicellular life forms that do not have an embryonic stage in their life cycle. Morphogenesis is essential for the evolution of new forms.

Morphogenesis is a mechanical process involving forces that generate mechanical stress, strain, and movement of cells,[1] and can be induced by genetic programs according to the spatial patterning of cells within tissues. Abnormal morphogenesis is called dysmorphogenesis.

History edit

Further information: Evolutionary developmental biology § History, and Turing pattern

Some of the earliest ideas and mathematical descriptions on how physical processes and constraints affect biological growth, and hence natural patterns such as the spirals of phyllotaxis, were written by D'Arcy Wentworth Thompson in his 1917 book On Growth and Form[2][3][note 1] and Alan Turing in his The Chemical Basis of Morphogenesis (1952).[6] Where Thompson explained animal body shapes as being created by varying rates of growth in different directions, for instance to create the spiral shell of a snail, Turing correctly predicted a mechanism of morphogenesis, the diffusion of two different chemical signals, one activating and one deactivating growth, to set up patterns of development, decades before the formation of such patterns was observed.[7] The fuller understanding of the mechanisms involved in actual organisms required the discovery of the structure of DNA in 1953, and the development of molecular biology and biochemistry.

Genetic and molecular basis edit

 
Morphogenesis is controlled by a "toolkit" of genes which switch development on and off at precise times and places. Here, gap genes in the fruit fly are switched on by genes such as bicoid, setting up stripes which create the body's segmental form.
Further information: evolutionary developmental biology, transcription factor, and gene regulatory network

Several types of molecules are important in morphogenesis. Morphogens are soluble molecules that can diffuse and carry signals that control cell differentiation via concentration gradients. Morphogens typically act through binding to specific protein receptors. An important class of molecules involved in morphogenesis are transcription factor proteins that determine the fate of cells by interacting with DNA. These can be coded for by master regulatory genes, and either activate or deactivate the transcription of other genes; in turn, these secondary gene products can regulate the expression of still other genes in a regulatory cascade of gene regulatory networks. At the end of this cascade are classes of molecules that control cellular behaviors such as cell migration, or, more generally, their properties, such as cell adhesion or cell contractility. For example, during gastrulation, clumps of stem cells switch off their cell-to-cell adhesion, become migratory, and take up new positions within an embryo where they again activate specific cell adhesion proteins and form new tissues and organs. Developmental signaling pathways implicated in morphogenesis include Wnt, Hedgehog, and ephrins.[8]

Cellular basis edit

 
Cell sorting out with cultured P19 embryonal carcinoma cells. Live cells were stained with DiI (red) or DiO (green). The red cells were genetically altered and express higher levels of E-cadherin than the green cells. The mixed culture forms large multi-cellular aggregates.

At a tissue level, ignoring the means of control, morphogenesis arises because of cellular proliferation and motility.[9] Morphogenesis also involves changes in the cellular structure[10] or how cells interact in tissues. These changes can result in tissue elongation, thinning, folding, invasion or separation of one tissue into distinct layers. The latter case is often referred as cell sorting. Cell "sorting out" consists of cells moving so as to sort into clusters that maximize contact between cells of the same type. The ability of cells to do this has been proposed to arise from differential cell adhesion by Malcolm Steinberg through his differential adhesion hypothesis. Tissue separation can also occur via more dramatic cellular differentiation events during which epithelial cells become mesenchymal (see Epithelial–mesenchymal transition). Mesenchymal cells typically leave the epithelial tissue as a consequence of changes in cell adhesive and contractile properties. Following epithelial-mesenchymal transition, cells can migrate away from an epithelium and then associate with other similar cells in a new location.[11] In plants, cellular morphogenesis is tightly linked to the chemical composition and the mechanical properties of the cell wall.[12][13]

Cell-to-cell adhesion edit

During embryonic development, cells are restricted to different layers due to differential affinities. One of the ways this can occur is when cells share the same cell-to-cell adhesion molecules. For instance, homotypic cell adhesion can maintain boundaries between groups of cells that have different adhesion molecules. Furthermore, cells can sort based upon differences in adhesion between the cells, so even two populations of cells with different levels of the same adhesion molecule can sort out. In cell culture cells that have the strongest adhesion move to the center of a mixed aggregates of cells. Moreover, cell-cell adhesion is often modulated by cell contractility, which can exert forces on the cell-cell contacts so that two cell populations with equal levels of the same adhesion molecule can sort out. The molecules responsible for adhesion are called cell adhesion molecules (CAMs). Several types of cell adhesion molecules are known and one major class of these molecules are cadherins. There are dozens of different cadherins that are expressed on different cell types. Cadherins bind to other cadherins in a like-to-like manner: E-cadherin (found on many epithelial cells) binds preferentially to other E-cadherin molecules. Mesenchymal cells usually express other cadherin types such as N-cadherin.[14][15]

Extracellular matrix edit

The extracellular matrix (ECM) is involved in keeping tissues separated, providing structural support or providing a structure for cells to migrate on. Collagen, laminin, and fibronectin are major ECM molecules that are secreted and assembled into sheets, fibers, and gels. Multisubunit transmembrane receptors called integrins are used to bind to the ECM. Integrins bind extracellularly to fibronectin, laminin, or other ECM components, and intracellularly to microfilament-binding proteins α-actinin and talin to link the cytoskeleton with the outside. Integrins also serve as receptors to trigger signal transduction cascades when binding to the ECM. A well-studied example of morphogenesis that involves ECM is mammary gland ductal branching.[16][17]

Cell contractility edit

Tissues can change their shape and separate into distinct layers via cell contractility. Just as in muscle cells, myosin can contract different parts of the cytoplasm to change its shape or structure. Myosin-driven contractility in embryonic tissue morphogenesis is seen during the separation of germ layers in the model organisms Caenorhabditis elegans, Drosophila and zebrafish. There are often periodic pulses of contraction in embryonic morphogenesis. A model called the cell state splitter involves alternating cell contraction and expansion, initiated by a bistable organelle at the apical end of each cell. The organelle consists of microtubules and microfilaments in mechanical opposition. It responds to local mechanical perturbations caused by morphogenetic movements. These then trigger traveling embryonic differentiation waves of contraction or expansion over presumptive tissues that determine cell type and is followed by cell differentiation. The cell state splitter was first proposed to explain neural plate morphogenesis during gastrulation of the axolotl[18] and the model was later generalized to all of morphogenesis.[19][20]

Branching morphogenesis edit

Further information: Lung § Development, and Breast development

In the development of the lung a bronchus branches into bronchioles forming the respiratory tree.[21] The branching is a result of the tip of each bronchiolar tube bifurcating, and the process of branching morphogenesis forms the bronchi, bronchioles, and ultimately the alveoli.[22]

Branching morphogenesis is also evident in the ductal formation of the mammary gland.[23][17] Primitive duct formation begins in development, but the branching formation of the duct system begins later in response to estrogen during puberty and is further refined in line with mammary gland development.[17][24][25]

Cancer morphogenesis edit

Cancer can result from disruption of normal morphogenesis, including both tumor formation and tumor metastasis.[26] Mitochondrial dysfunction can result in increased cancer risk due to disturbed morphogen signaling.[26]

Virus morphogenesis edit

During assembly of the bacteriophage (phage) T4 virion, the morphogenetic proteins encoded by the phage genes interact with each other in a characteristic sequence. Maintaining an appropriate balance in the amounts of each of these proteins produced during viral infection appears to be critical for normal phage T4 morphogenesis.[27] Phage T4 encoded proteins that determine virion structure include major structural components, minor structural components and non-structural proteins that catalyze specific steps in the morphogenesis sequence.[28] Phage T4 morphogenesis is divided into three independent pathways: the head, the tail and the long tail fibres as detailed by Yap and Rossman.[29]

Computer models edit

An approach to model morphogenesis in computer science or mathematics can be traced to Alan Turing's 1952 paper, "The chemical basis of morphogenesis",[30] a model now known as the Turing pattern.

Another famous model is the so-called French flag model, developed in the sixties.[31]

Improvements in computer performance in the twenty-first century enabled the simulation of relatively complex morphogenesis models. In 2020, such a model was proposed where cell growth and differentiation is that of a cellular automaton with parametrized rules. As the rules' parameters are differentiable, they can be trained with gradient descent, a technique which has been highly optimized in recent years due to its use in machine learning.[32] This model was limited to the generation of pictures, and is thus bi-dimensional.

A similar model to the one described above was subsequently extended to generate three-dimensional structures, and was demonstrated in the video game Minecraft, whose block-based nature made it particularly expedient for the simulation of 3D cellular automatons.[33]

See also edit

Notes edit

  1. ^ Thompson's book is often cited. An abridged version, comprising 349 pages, remains in print and readily obtainable.[4] An unabridged version, comprising 1116 pages, has also been published.[5]

References edit

  1. ^ Bidhendi, Amir J.; Altartouri, Bara; Gosselin, Frédérick P.; Geitmann, Anja (July 2019). "Mechanical stress initiates and sustains the morphogenesis of wavy leaf epidermal cells". Cell Reports. 28 (5): 1237–1250. doi:10.1016/j.celrep.2019.07.006. PMID 31365867.
  2. ^ Thompson, D'Arcy Wentworth (1917). On Growth and Form. Cambridge University Press.
  3. ^ Montell, Denise J. (5 December 2008), (PDF), Science, 322 (5907): 1502–1505, Bibcode:2008Sci...322.1502M, doi:10.1126/science.1164073, PMID 19056976, S2CID 27982230, archived from the original (PDF) on 28 November 2014, retrieved 11 December 2012
  4. ^ Thompson, D'Arcy Wentworth (2004) [1917, abridged 1961], Bonner, John Tyler (ed.), On Growth and Form, Cambridge, England; New York, NY: Cambridge University Press, ISBN 978-0-521-43776-9, retrieved 11 December 2012
  5. ^ Thompson, D'Arcy Wentworth (1992), On Growth and Form: The Complete Revised Edition, New York, NY: Dover, ISBN 978-0-486-67135-2
  6. ^ Turing, A. M. (1952). "The Chemical Basis of Morphogenesis". Philosophical Transactions of the Royal Society B. 237 (641): 37–72. Bibcode:1952RSPTB.237...37T. doi:10.1098/rstb.1952.0012.
  7. ^ Hiscock, Tom W.; Megason, Sean G. (2015). "Orientation of Turing-like Patterns by Morphogen Gradients and Tissue Anisotropies". Cell Systems. 1 (6): 408–416. doi:10.1016/j.cels.2015.12.001. PMC 4707970. PMID 26771020.
  8. ^ Kouros-Mehr, H.; Werb, Z. (2006). "Candidate regulators of mammary branching morphogenesis identified by genome-wide transcript analysis". Dev. Dyn. 235 (12): 3404–12. doi:10.1002/dvdy.20978. PMC 2730892. PMID 17039550.
  9. ^ Montévil, Maël; Speroni, Lucia; Sonnenschein, Carlos; Soto, Ana M. (2016). "Modeling mammary organogenesis from biological first principles: Cells and their physical constraints". Progress in Biophysics and Molecular Biology. From the Century of the Genome to the Century of the Organism: New Theoretical Approaches. 122 (1): 58–69. arXiv:1702.03337. doi:10.1016/j.pbiomolbio.2016.08.004. PMC 5563449. PMID 27544910.
  10. ^ Duran-Nebreda, Salva; Pla, Jordi; Vidiella, Blai; Piñero, Jordi; Conde-Pueyo, Nuria; Solé, Ricard (2021-01-15). "Synthetic Lateral Inhibition in Periodic Pattern Forming Microbial Colonies". ACS Synthetic Biology. 10 (2): 277–285. doi:10.1021/acssynbio.0c00318. ISSN 2161-5063. PMC 8486170. PMID 33449631.
  11. ^ Gilbert, Scott F. (2000). "Morphogenesis and Cell Adhesion". Developmental biology (6th ed.). Sunderland, Mass: Sinauer Associates. ISBN 978-0-87893-243-6.
  12. ^ Bidhendi, Amir J; Geitmann, Anja (January 2016). "Relating the mechanical properties of the primary plant cell wall to morphogenesis" (PDF). Journal of Experimental Botany. 67 (2): 449–461. doi:10.1093/jxb/erv535. PMID 26689854.
  13. ^ Bidhendi, Amir J; Geitmann, Anja (January 2018). "Finite element modeling of shape changes in plant cells". Plant Physiology. 176 (1): 41–56. doi:10.1104/pp.17.01684. PMC 5761827. PMID 29229695.
  14. ^ Hulpiau, P.; van Roy, F. (February 2009). "Molecular evolution of the cadherin superfamily". Int. J. Biochem. Cell Biol. 41 (2): 349–69. doi:10.1016/j.biocel.2008.09.027. PMID 18848899.
  15. ^ Angst, B.; Marcozzi, C.; Magee, A. (February 2001). "The cadherin superfamily: diversity in form and function". J Cell Sci. 114 (Pt 4): 629–41. doi:10.1242/jcs.114.4.629. PMID 11171368.
  16. ^ Fata JE, Werb Z, Bissell MJ (2004). "Regulation of mammary gland branching morphogenesis by the extracellular matrix and its remodeling enzymes". Breast Cancer Res. 6 (1): 1–11. doi:10.1186/bcr634. PMC 314442. PMID 14680479.
  17. ^ a b c Sternlicht MD (2006). "Key stages in mammary gland development: the cues that regulate ductal branching morphogenesis". Breast Cancer Res. 8 (1): 201. doi:10.1186/bcr1368. PMC 1413974. PMID 16524451.
  18. ^ Gordon, Richard; Brodland, G. Wayne (1987). "The cytoskeletal mechanics of brain morphogenesis". Cell Biophysics. 11: 177–238. doi:10.1007/BF02797122. PMID 2450659. S2CID 4349055.
  19. ^ Gordon, Natalie K.; Gordon, Richard (2016). "The organelle of differentiation in embryos: The cell state splitter". Theoretical Biology and Medical Modelling. 13: 11. doi:10.1186/s12976-016-0037-2. PMC 4785624. PMID 26965444.
  20. ^ Gordon, Natalie K.; Gordon, Richard (2016). Embryogenesis Explained. doi:10.1142/8152. ISBN 978-981-4350-48-8.
  21. ^ Wolpert, Lewis (2015). Principles of development (5th ed.). Oxford University Press. pp. 499–500. ISBN 978-0-19-967814-3.
  22. ^ Miura, T (2008). "Modeling Lung Branching Morphogenesis". Multiscale Modeling of Developmental Systems. Current Topics in Developmental Biology. Vol. 81. pp. 291–310. doi:10.1016/S0070-2153(07)81010-6. ISBN 9780123742537. PMID 18023732.
  23. ^ Fata JE, Werb Z, Bissell MJ (2004). "Regulation of mammary gland branching morphogenesis by the extracellular matrix and its remodeling enzymes". Breast Cancer Res. 6 (1): 1–11. doi:10.1186/bcr634. PMC 314442. PMID 14680479.
  24. ^ Hynes, N. E.; Watson, C. J. (2010). "Mammary Gland Growth Factors: Roles in Normal Development and in Cancer". Cold Spring Harbor Perspectives in Biology. 2 (8): a003186. doi:10.1101/cshperspect.a003186. ISSN 1943-0264. PMC 2908768. PMID 20554705.
  25. ^ Jay R. Harris; Marc E. Lippman; C. Kent Osborne; Monica Morrow (28 March 2012). Diseases of the Breast. Lippincott Williams & Wilkins. pp. 94–. ISBN 978-1-4511-4870-1.
  26. ^ a b Fosslien E (2008). (PDF). Annals of Clinical & Laboratory Science. 38 (4): 307–329. PMID 18988924. S2CID 4538888. Archived from the original (PDF) on 2017-09-21.
  27. ^ Floor, Erik (1970). "Interaction of morphogenetic genes of bacteriophage T4". Journal of Molecular Biology. 47 (3): 293–306. doi:10.1016/0022-2836(70)90303-7. PMID 4907266.
  28. ^ Snustad, D.Peter (1968). "Dominance interactions in Escherichia coli cells mixedly infected with bacteriophage T4D wild-type and amber mutants and their possible implications as to type of gene-product function: Catalytic vs. Stoichiometric". Virology. 35 (4): 550–563. doi:10.1016/0042-6822(68)90285-7. PMID 4878023.
  29. ^ Yap, Moh Lan; Rossmann, Michael G. (2014). "Structure and function of bacteriophage T4". Future Microbiology. 9 (12): 1319–1327. doi:10.2217/fmb.14.91. PMC 4275845. PMID 25517898.
  30. ^ Turing, Alan Mathison (1952). "The chemical basis of morphogenesis". Philosophical Transactions of the Royal Society B. 237 (641): 37–72. Bibcode:1952RSPTB.237...37T. doi:10.1098/rstb.1952.0012. S2CID 937133.
  31. ^ Sharpe, James; Green, Jeremy (2015). "Positional information and reaction-diffusion: two big ideas in developmental biology combine". Development. 142 (7): 1203–1211. doi:10.1242/dev.114991. hdl:10230/25028. PMID 25804733.
  32. ^ Mordvintsev, Alexander; Randazzo, Ettore; Niklasson, Eyvind; Levin, Michael (2020). "Growing Neural Cellular Automata". Distill. 5 (2). doi:10.23915/distill.00023. S2CID 213719058.
  33. ^ Sudhakaran, Shyam; Grbic, Djordje; Li, Siyan; Katona, Adam; Najarro, Elias; Glanois, Claire; Risi, Sebastian (2021). "Growing 3D Artefacts and Functional Machines with Neural Cellular Automata". arXiv:2103.08737 [cs.LG].

Further reading edit

  • Bard, J. B. L. (1990). Morphogenesis: The Cellular and Molecular Processes of Developmental Anatomy. Cambridge, England: Cambridge University Press.
  • Slack, J. M. W. (2013). Essential Developmental Biology. Oxford: Wiley-Blackwell.

External links edit

 
Wikimedia Commons has media related to Morphogenesis.
  • Artificial Life model of multicellular morphogenesis with autonomously generated gradients for positional information
  • Turing's theory of morphogenesis validated

February 15, 2024
morphogenesis, this, article, about, biological, process, other, uses, disambiguation, from, greek, morphê, shape, genesis, creation, literally, generation, form, biological, process, that, causes, cell, tissue, organism, develop, shape, three, fundamental, as. This article is about the biological process For other uses see Morphogenesis disambiguation Morphogenesis from the Greek morphe shape and genesis creation literally the generation of form is the biological process that causes a cell tissue or organism to develop its shape It is one of three fundamental aspects of developmental biology along with the control of tissue growth and patterning of cellular differentiation The process controls the organized spatial distribution of cells during the embryonic development of an organism Morphogenesis can take place also in a mature organism such as in the normal maintenance of tissue by stem cells or in regeneration of tissues after damage Cancer is an example of highly abnormal and pathological tissue morphogenesis Morphogenesis also describes the development of unicellular life forms that do not have an embryonic stage in their life cycle Morphogenesis is essential for the evolution of new forms Morphogenesis is a mechanical process involving forces that generate mechanical stress strain and movement of cells 1 and can be induced by genetic programs according to the spatial patterning of cells within tissues Abnormal morphogenesis is called dysmorphogenesis Contents 1 History 2 Genetic and molecular basis 3 Cellular basis 3 1 Cell to cell adhesion 3 2 Extracellular matrix 3 3 Cell contractility 3 4 Branching morphogenesis 4 Cancer morphogenesis 5 Virus morphogenesis 6 Computer models 7 See also 8 Notes 9 References 10 Further reading 11 External linksHistory editFurther information Evolutionary developmental biology History and Turing pattern Some of the earliest ideas and mathematical descriptions on how physical processes and constraints affect biological growth and hence natural patterns such as the spirals of phyllotaxis were written by D Arcy Wentworth Thompson in his 1917 book On Growth and Form 2 3 note 1 and Alan Turing in his The Chemical Basis of Morphogenesis 1952 6 Where Thompson explained animal body shapes as being created by varying rates of growth in different directions for instance to create the spiral shell of a snail Turing correctly predicted a mechanism of morphogenesis the diffusion of two different chemical signals one activating and one deactivating growth to set up patterns of development decades before the formation of such patterns was observed 7 The fuller understanding of the mechanisms involved in actual organisms required the discovery of the structure of DNA in 1953 and the development of molecular biology and biochemistry Genetic and molecular basis edit nbsp Morphogenesis is controlled by a toolkit of genes which switch development on and off at precise times and places Here gap genes in the fruit fly are switched on by genes such as bicoid setting up stripes which create the body s segmental form Further information evolutionary developmental biology transcription factor and gene regulatory network Several types of molecules are important in morphogenesis Morphogens are soluble molecules that can diffuse and carry signals that control cell differentiation via concentration gradients Morphogens typically act through binding to specific protein receptors An important class of molecules involved in morphogenesis are transcription factor proteins that determine the fate of cells by interacting with DNA These can be coded for by master regulatory genes and either activate or deactivate the transcription of other genes in turn these secondary gene products can regulate the expression of still other genes in a regulatory cascade of gene regulatory networks At the end of this cascade are classes of molecules that control cellular behaviors such as cell migration or more generally their properties such as cell adhesion or cell contractility For example during gastrulation clumps of stem cells switch off their cell to cell adhesion become migratory and take up new positions within an embryo where they again activate specific cell adhesion proteins and form new tissues and organs Developmental signaling pathways implicated in morphogenesis include Wnt Hedgehog and ephrins 8 Cellular basis edit nbsp Cell sorting out with cultured P19 embryonal carcinoma cells Live cells were stained with DiI red or DiO green The red cells were genetically altered and express higher levels of E cadherin than the green cells The mixed culture forms large multi cellular aggregates At a tissue level ignoring the means of control morphogenesis arises because of cellular proliferation and motility 9 Morphogenesis also involves changes in the cellular structure 10 or how cells interact in tissues These changes can result in tissue elongation thinning folding invasion or separation of one tissue into distinct layers The latter case is often referred as cell sorting Cell sorting out consists of cells moving so as to sort into clusters that maximize contact between cells of the same type The ability of cells to do this has been proposed to arise from differential cell adhesion by Malcolm Steinberg through his differential adhesion hypothesis Tissue separation can also occur via more dramatic cellular differentiation events during which epithelial cells become mesenchymal see Epithelial mesenchymal transition Mesenchymal cells typically leave the epithelial tissue as a consequence of changes in cell adhesive and contractile properties Following epithelial mesenchymal transition cells can migrate away from an epithelium and then associate with other similar cells in a new location 11 In plants cellular morphogenesis is tightly linked to the chemical composition and the mechanical properties of the cell wall 12 13 Cell to cell adhesion edit During embryonic development cells are restricted to different layers due to differential affinities One of the ways this can occur is when cells share the same cell to cell adhesion molecules For instance homotypic cell adhesion can maintain boundaries between groups of cells that have different adhesion molecules Furthermore cells can sort based upon differences in adhesion between the cells so even two populations of cells with different levels of the same adhesion molecule can sort out In cell culture cells that have the strongest adhesion move to the center of a mixed aggregates of cells Moreover cell cell adhesion is often modulated by cell contractility which can exert forces on the cell cell contacts so that two cell populations with equal levels of the same adhesion molecule can sort out The molecules responsible for adhesion are called cell adhesion molecules CAMs Several types of cell adhesion molecules are known and one major class of these molecules are cadherins There are dozens of different cadherins that are expressed on different cell types Cadherins bind to other cadherins in a like to like manner E cadherin found on many epithelial cells binds preferentially to other E cadherin molecules Mesenchymal cells usually express other cadherin types such as N cadherin 14 15 Extracellular matrix edit The extracellular matrix ECM is involved in keeping tissues separated providing structural support or providing a structure for cells to migrate on Collagen laminin and fibronectin are major ECM molecules that are secreted and assembled into sheets fibers and gels Multisubunit transmembrane receptors called integrins are used to bind to the ECM Integrins bind extracellularly to fibronectin laminin or other ECM components and intracellularly to microfilament binding proteins a actinin and talin to link the cytoskeleton with the outside Integrins also serve as receptors to trigger signal transduction cascades when binding to the ECM A well studied example of morphogenesis that involves ECM is mammary gland ductal branching 16 17 Cell contractility edit Tissues can change their shape and separate into distinct layers via cell contractility Just as in muscle cells myosin can contract different parts of the cytoplasm to change its shape or structure Myosin driven contractility in embryonic tissue morphogenesis is seen during the separation of germ layers in the model organisms Caenorhabditis elegans Drosophila and zebrafish There are often periodic pulses of contraction in embryonic morphogenesis A model called the cell state splitter involves alternating cell contraction and expansion initiated by a bistable organelle at the apical end of each cell The organelle consists of microtubules and microfilaments in mechanical opposition It responds to local mechanical perturbations caused by morphogenetic movements These then trigger traveling embryonic differentiation waves of contraction or expansion over presumptive tissues that determine cell type and is followed by cell differentiation The cell state splitter was first proposed to explain neural plate morphogenesis during gastrulation of the axolotl 18 and the model was later generalized to all of morphogenesis 19 20 Branching morphogenesis edit Further information Lung Development and Breast development In the development of the lung a bronchus branches into bronchioles forming the respiratory tree 21 The branching is a result of the tip of each bronchiolar tube bifurcating and the process of branching morphogenesis forms the bronchi bronchioles and ultimately the alveoli 22 Branching morphogenesis is also evident in the ductal formation of the mammary gland 23 17 Primitive duct formation begins in development but the branching formation of the duct system begins later in response to estrogen during puberty and is further refined in line with mammary gland development 17 24 25 Cancer morphogenesis editCancer can result from disruption of normal morphogenesis including both tumor formation and tumor metastasis 26 Mitochondrial dysfunction can result in increased cancer risk due to disturbed morphogen signaling 26 Virus morphogenesis editDuring assembly of the bacteriophage phage T4 virion the morphogenetic proteins encoded by the phage genes interact with each other in a characteristic sequence Maintaining an appropriate balance in the amounts of each of these proteins produced during viral infection appears to be critical for normal phage T4 morphogenesis 27 Phage T4 encoded proteins that determine virion structure include major structural components minor structural components and non structural proteins that catalyze specific steps in the morphogenesis sequence 28 Phage T4 morphogenesis is divided into three independent pathways the head the tail and the long tail fibres as detailed by Yap and Rossman 29 Computer models editAn approach to model morphogenesis in computer science or mathematics can be traced to Alan Turing s 1952 paper The chemical basis of morphogenesis 30 a model now known as the Turing pattern Another famous model is the so called French flag model developed in the sixties 31 Improvements in computer performance in the twenty first century enabled the simulation of relatively complex morphogenesis models In 2020 such a model was proposed where cell growth and differentiation is that of a cellular automaton with parametrized rules As the rules parameters are differentiable they can be trained with gradient descent a technique which has been highly optimized in recent years due to its use in machine learning 32 This model was limited to the generation of pictures and is thus bi dimensional A similar model to the one described above was subsequently extended to generate three dimensional structures and was demonstrated in the video game Minecraft whose block based nature made it particularly expedient for the simulation of 3D cellular automatons 33 See also editBone morphogenetic protein Collective cell migration Embryonic development Pattern formation Reaction diffusion system Neurulation Gastrulation Axon guidance Eye development Polycystic kidney disease 2 Drosophila embryogenesis Cytoplasmic determinant Madin Darby Canine Kidney cells Bioelectricity Role in pattern regulationNotes edit Thompson s book is often cited An abridged version comprising 349 pages remains in print and readily obtainable 4 An unabridged version comprising 1116 pages has also been published 5 References edit Bidhendi Amir J Altartouri Bara Gosselin Frederick P Geitmann Anja July 2019 Mechanical stress initiates and sustains the morphogenesis of wavy leaf epidermal cells Cell Reports 28 5 1237 1250 doi 10 1016 j celrep 2019 07 006 PMID 31365867 Thompson D Arcy Wentworth 1917 On Growth and Form Cambridge University Press Montell Denise J 5 December 2008 Morphogenetic Cell Movements Diversity from Modular Mechanical Properties PDF Science 322 5907 1502 1505 Bibcode 2008Sci 322 1502M doi 10 1126 science 1164073 PMID 19056976 S2CID 27982230 archived from the original PDF on 28 November 2014 retrieved 11 December 2012 Thompson D Arcy Wentworth 2004 1917 abridged 1961 Bonner John Tyler ed On Growth and Form Cambridge England New York NY Cambridge University Press ISBN 978 0 521 43776 9 retrieved 11 December 2012 Thompson D Arcy Wentworth 1992 On Growth and Form The Complete Revised Edition New York NY Dover ISBN 978 0 486 67135 2 Turing A M 1952 The Chemical Basis of Morphogenesis Philosophical Transactions of the Royal Society B 237 641 37 72 Bibcode 1952RSPTB 237 37T doi 10 1098 rstb 1952 0012 Hiscock Tom W Megason Sean G 2015 Orientation of Turing like Patterns by Morphogen Gradients and Tissue Anisotropies Cell Systems 1 6 408 416 doi 10 1016 j cels 2015 12 001 PMC 4707970 PMID 26771020 Kouros Mehr H Werb Z 2006 Candidate regulators of mammary branching morphogenesis identified by genome wide transcript analysis Dev Dyn 235 12 3404 12 doi 10 1002 dvdy 20978 PMC 2730892 PMID 17039550 Montevil Mael Speroni Lucia Sonnenschein Carlos Soto Ana M 2016 Modeling mammary organogenesis from biological first principles Cells and their physical constraints Progress in Biophysics and Molecular Biology From the Century of the Genome to the Century of the Organism New Theoretical Approaches 122 1 58 69 arXiv 1702 03337 doi 10 1016 j pbiomolbio 2016 08 004 PMC 5563449 PMID 27544910 Duran Nebreda Salva Pla Jordi Vidiella Blai Pinero Jordi Conde Pueyo Nuria Sole Ricard 2021 01 15 Synthetic Lateral Inhibition in Periodic Pattern Forming Microbial Colonies ACS Synthetic Biology 10 2 277 285 doi 10 1021 acssynbio 0c00318 ISSN 2161 5063 PMC 8486170 PMID 33449631 Gilbert Scott F 2000 Morphogenesis and Cell Adhesion Developmental biology 6th ed Sunderland Mass Sinauer Associates ISBN 978 0 87893 243 6 Bidhendi Amir J Geitmann Anja January 2016 Relating the mechanical properties of the primary plant cell wall to morphogenesis PDF Journal of Experimental Botany 67 2 449 461 doi 10 1093 jxb erv535 PMID 26689854 Bidhendi Amir J Geitmann Anja January 2018 Finite element modeling of shape changes in plant cells Plant Physiology 176 1 41 56 doi 10 1104 pp 17 01684 PMC 5761827 PMID 29229695 Hulpiau P van Roy F February 2009 Molecular evolution of the cadherin superfamily Int J Biochem Cell Biol 41 2 349 69 doi 10 1016 j biocel 2008 09 027 PMID 18848899 Angst B Marcozzi C Magee A February 2001 The cadherin superfamily diversity in form and function J Cell Sci 114 Pt 4 629 41 doi 10 1242 jcs 114 4 629 PMID 11171368 Fata JE Werb Z Bissell MJ 2004 Regulation of mammary gland branching morphogenesis by the extracellular matrix and its remodeling enzymes Breast Cancer Res 6 1 1 11 doi 10 1186 bcr634 PMC 314442 PMID 14680479 a b c Sternlicht MD 2006 Key stages in mammary gland development the cues that regulate ductal branching morphogenesis Breast Cancer Res 8 1 201 doi 10 1186 bcr1368 PMC 1413974 PMID 16524451 Gordon Richard Brodland G Wayne 1987 The cytoskeletal mechanics of brain morphogenesis Cell Biophysics 11 177 238 doi 10 1007 BF02797122 PMID 2450659 S2CID 4349055 Gordon Natalie K Gordon Richard 2016 The organelle of differentiation in embryos The cell state splitter Theoretical Biology and Medical Modelling 13 11 doi 10 1186 s12976 016 0037 2 PMC 4785624 PMID 26965444 Gordon Natalie K Gordon Richard 2016 Embryogenesis Explained doi 10 1142 8152 ISBN 978 981 4350 48 8 Wolpert Lewis 2015 Principles of development 5th ed Oxford University Press pp 499 500 ISBN 978 0 19 967814 3 Miura T 2008 Modeling Lung Branching Morphogenesis Multiscale Modeling of Developmental Systems Current Topics in Developmental Biology Vol 81 pp 291 310 doi 10 1016 S0070 2153 07 81010 6 ISBN 9780123742537 PMID 18023732 Fata JE Werb Z Bissell MJ 2004 Regulation of mammary gland branching morphogenesis by the extracellular matrix and its remodeling enzymes Breast Cancer Res 6 1 1 11 doi 10 1186 bcr634 PMC 314442 PMID 14680479 Hynes N E Watson C J 2010 Mammary Gland Growth Factors Roles in Normal Development and in Cancer Cold Spring Harbor Perspectives in Biology 2 8 a003186 doi 10 1101 cshperspect a003186 ISSN 1943 0264 PMC 2908768 PMID 20554705 Jay R Harris Marc E Lippman C Kent Osborne Monica Morrow 28 March 2012 Diseases of the Breast Lippincott Williams amp Wilkins pp 94 ISBN 978 1 4511 4870 1 a b Fosslien E 2008 Cancer morphogenesis role of mitochondrial failure PDF Annals of Clinical amp Laboratory Science 38 4 307 329 PMID 18988924 S2CID 4538888 Archived from the original PDF on 2017 09 21 Floor Erik 1970 Interaction of morphogenetic genes of bacteriophage T4 Journal of Molecular Biology 47 3 293 306 doi 10 1016 0022 2836 70 90303 7 PMID 4907266 Snustad D Peter 1968 Dominance interactions in Escherichia coli cells mixedly infected with bacteriophage T4D wild type and amber mutants and their possible implications as to type of gene product function Catalytic vs Stoichiometric Virology 35 4 550 563 doi 10 1016 0042 6822 68 90285 7 PMID 4878023 Yap Moh Lan Rossmann Michael G 2014 Structure and function of bacteriophage T4 Future Microbiology 9 12 1319 1327 doi 10 2217 fmb 14 91 PMC 4275845 PMID 25517898 Turing Alan Mathison 1952 The chemical basis of morphogenesis Philosophical Transactions of the Royal Society B 237 641 37 72 Bibcode 1952RSPTB 237 37T doi 10 1098 rstb 1952 0012 S2CID 937133 Sharpe James Green Jeremy 2015 Positional information and reaction diffusion two big ideas in developmental biology combine Development 142 7 1203 1211 doi 10 1242 dev 114991 hdl 10230 25028 PMID 25804733 Mordvintsev Alexander Randazzo Ettore Niklasson Eyvind Levin Michael 2020 Growing Neural Cellular Automata Distill 5 2 doi 10 23915 distill 00023 S2CID 213719058 Sudhakaran Shyam Grbic Djordje Li Siyan Katona Adam Najarro Elias Glanois Claire Risi Sebastian 2021 Growing 3D Artefacts and Functional Machines with Neural Cellular Automata arXiv 2103 08737 cs LG Further reading editBard J B L 1990 Morphogenesis The Cellular and Molecular Processes of Developmental Anatomy Cambridge England Cambridge University Press Slack J M W 2013 Essential Developmental Biology Oxford Wiley Blackwell External links edit nbsp Wikimedia Commons has media related to Morphogenesis Artificial Life model of multicellular morphogenesis with autonomously generated gradients for positional information Turing s theory of morphogenesis validated Portal nbsp Biology Retrieved from https en wikipedia org w index php title Morphogenesis amp oldid 1195414044, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.