Bioelectric memory: modeling resting potential bistability in amphibian embryos and mammalian cells
暂无分享,去创建一个
[1] C. Pullar. The physiology of bioelectricity in development, tissue regeneration, and cancer , 2016 .
[2] M. Levin,et al. Endogenous Gradients of Resting Potential Instructively Pattern Embryonic Neural Tissue via Notch Signaling and Regulation of Proliferation , 2015, The Journal of Neuroscience.
[3] A. Masotti,et al. Keppen-Lubinsky syndrome is caused by mutations in the inwardly rectifying K+ channel encoded by KCNJ6. , 2015, American journal of human genetics.
[4] M. Levin,et al. Long-range gap junctional signaling controls oncogene-mediated tumorigenesis in Xenopus laevis embryos , 2015, Front. Physiol..
[5] J. Bohrmann,et al. Bioelectric patterning during oogenesis: stage-specific distribution of membrane potentials, intracellular pH and ion-transport mechanisms in Drosophila ovarian follicles , 2015, BMC Developmental Biology.
[6] S. Bendahhou,et al. The inward rectifier potassium channel Kir2.1 is required for osteoblastogenesis. , 2015, Human molecular genetics.
[7] Frank Jülicher,et al. Scaling and regeneration of self-organized patterns. , 2014, Physical review letters.
[8] M. Levin,et al. A Novel Method for Inducing Nerve Growth via Modulation of Host Resting Potential: Gap Junction-Mediated and Serotonergic Signaling Mechanisms , 2014, Neurotherapeutics.
[9] Michael Levin,et al. Molecular bioelectricity: how endogenous voltage potentials control cell behavior and instruct pattern regulation in vivo , 2014, Molecular biology of the cell.
[10] A. Alcaraz,et al. Membrane potential bistability in nonexcitable cells as described by inward and outward voltage-gated ion channels. , 2014, The journal of physical chemistry. B.
[11] MustardJessica,et al. Bioelectrical Mechanisms for Programming Growth and Form: Taming Physiological Networks for Soft Body Robotics , 2014 .
[12] Michael Clerx,et al. Myokit: A framework for computational cellular electrophysiology , 2014, Computing in Cardiology 2014.
[13] DoursatRené,et al. Growing Fine-Grained Multicellular Robots , 2014 .
[14] Michael Levin,et al. A linear-encoding model explains the variability of the target morphology in regeneration , 2014, Journal of The Royal Society Interface.
[15] G. Hoge,et al. Corrigendum to “Gap junction-mediated electrical transmission: Regulatory mechanisms and plasticity” [Biochim. Biophys. Acta 1828 (2013) 134–146] , 2014 .
[16] Stephen L. Johnson,et al. Bioelectric Signaling Regulates Size in Zebrafish Fins , 2014, PLoS genetics.
[17] Lutz Brusch,et al. Mathematical modeling of regenerative processes. , 2014, Current topics in developmental biology.
[18] R. Doursat,et al. Growing Fine-Grained Multicellular Robots , 2014 .
[19] M. Levin,et al. Endogenous Voltage Potentials and the Microenvironment: Bioelectric Signals that Reveal, Induce and Normalize Cancer. , 2014, Journal of clinical & experimental oncology.
[20] R. Bashir,et al. Creating Living Cellular Machines , 2014, Annals of Biomedical Engineering.
[21] Michael Levin,et al. Reprogramming cells and tissue patterning via bioelectrical pathways: molecular mechanisms and biomedical opportunities , 2013, Wiley interdisciplinary reviews. Systems biology and medicine.
[22] S. Waxman,et al. Noncanonical Roles of Voltage-Gated Sodium Channels , 2013, Neuron.
[23] D. Kaplan,et al. Depolarization alters phenotype, maintains plasticity of predifferentiated mesenchymal stem cells. , 2013, Tissue engineering. Part A.
[24] M. Burd,et al. Evaluating the spectral discrimination capabilities of different pollinators and their effect on the evolution of flower colors , 2013, Communicative & integrative biology.
[25] M. Levin,et al. Light-activation of the Archaerhodopsin H+-pump reverses age-dependent loss of vertebrate regeneration: sparking system-level controls in vivo , 2013, Biology Open.
[26] G. Hoge,et al. Gap junction-mediated electrical transmission: regulatory mechanisms and plasticity. , 2013, Biochimica et biophysica acta.
[27] M. Levin,et al. Endogenous voltage gradients as mediators of cell-cell communication: strategies for investigating bioelectrical signals during pattern formation , 2013, Cell and Tissue Research.
[28] M. Levin,et al. Resting potential, oncogene-induced tumorigenesis, and metastasis: the bioelectric basis of cancer in vivo , 2012, Physical biology.
[29] M. Djamgoz,et al. Voltage-gated sodium channel activity promotes prostate cancer metastasis in vivo. , 2012, Cancer letters.
[30] Michael Levin,et al. Transducing Bioelectric Signals into Epigenetic Pathways During Tadpole Tail Regeneration , 2012, Anatomical record.
[31] L. Ptáček,et al. An inwardly rectifying K+ channel is required for patterning , 2012, Development.
[32] M. Levin,et al. Regulation of cell behavior and tissue patterning by bioelectrical signals: challenges and opportunities for biomedical engineering. , 2012, Annual review of biomedical engineering.
[33] W. Brackenbury,et al. Therapeutic potential for phenytoin: targeting Nav1.5 sodium channels to reduce migration and invasion in metastatic breast cancer , 2012, Breast Cancer Research and Treatment.
[34] M. Levin,et al. Measuring resting membrane potential using the fluorescent voltage reporters DiBAC4(3) and CC2-DMPE. , 2012, Cold Spring Harbor protocols.
[35] M. Levin. Molecular bioelectricity in developmental biology: New tools and recent discoveries , 2012, BioEssays : news and reviews in molecular, cellular and developmental biology.
[36] Michael Levin,et al. Transmembrane voltage potential controls embryonic eye patterning in Xenopus laevis , 2012, Development.
[37] Henry Markram,et al. Channelpedia: An Integrative and Interactive Database for Ion Channels , 2011, Front. Neuroinform..
[38] J. Nerbonne,et al. Characterization of a novel, dominant negative KCNJ2 mutation associated with Andersen-Tawil syndrome , 2011, Channels.
[39] Ryan D Morrie,et al. V‐ATPase‐dependent ectodermal voltage and ph regionalization are required for craniofacial morphogenesis , 2011, Developmental dynamics : an official publication of the American Association of Anatomists.
[40] Timothy W. Dunn,et al. Optogenetic Photochemical Control of Designer K Ϩ Channels in Mammalian Neurons , 2022 .
[41] V. Taylor,et al. The H(+) vacuolar ATPase maintains neural stem cells in the developing mouse cortex. , 2011, Stem cells and development.
[42] M. Kamate,et al. Andersen-Tawil syndrome — Periodic paralysis with dysmorphism , 2011, Indian pediatrics.
[43] Michael Levin,et al. A chemical genetics approach reveals H,K-ATPase-mediated membrane voltage is required for planarian head regeneration. , 2011, Chemistry & biology.
[44] M. Levin,et al. Transmembrane potential of GlyCl-expressing instructor cells induces a neoplastic-like conversion of melanocytes via a serotonergic pathway , 2010, Disease Models & Mechanisms.
[45] Abiche H. Dewilde,et al. BioDome regenerative sleeve for biochemical and biophysical stimulation of tissue regeneration. , 2010, Medical engineering & physics.
[46] Michael Levin,et al. Induction of Vertebrate Regeneration by a Transient Sodium Current , 2010, The Journal of Neuroscience.
[47] Martin Tristani-Firouzi,et al. Kir 2.1 channelopathies: the Andersen–Tawil syndrome , 2010, Pflügers Archiv - European Journal of Physiology.
[48] M. Djamgoz,et al. Molecular pharmacology of voltage-gated sodium channel expression in metastatic disease: clinical potential of neonatal Nav1.5 in breast cancer. , 2009, European journal of pharmacology.
[49] Michael Levin,et al. Bioelectric controls of cell proliferation: Ion channels, membrane voltage and the cell cycle , 2009, Cell cycle.
[50] Feliksas F. Bukauskas,et al. Heterotypic gap junction channels as voltage-sensitive valves for intercellular signaling , 2009, Proceedings of the National Academy of Sciences.
[51] David L. Kaplan,et al. Role of Membrane Potential in the Regulation of Cell Proliferation and Differentiation , 2009, Stem Cell Reviews and Reports.
[52] T. Darland,et al. The vacuolar-ATPase complex regulates retinoblast proliferation and survival, photoreceptor morphogenesis, and pigmentation in the zebrafish eye. , 2009, Investigative ophthalmology & visual science.
[53] David L. Kaplan,et al. Membrane Potential Controls Adipogenic and Osteogenic Differentiation of Mesenchymal Stem Cells , 2008, PloS one.
[54] D. Adams,et al. A new tool for tissue engineers: ions as regulators of morphogenesis during development and regeneration. , 2008, Tissue engineering. Part A.
[55] D. Shao,et al. Alternative splicing of Nav1.5: An electrophysiological comparison of ‘neonatal’ and ‘adult’ isoforms and critical involvement of a lysine residue , 2008, Journal of cellular physiology.
[56] M. Levin,et al. KCNQ1 and KCNE1 K+ Channel Components are Involved in Early Left-Right Patterning in Xenopus laevis Embryos , 2008, Cellular Physiology and Biochemistry.
[57] C. Bader,et al. Initiation of human myoblast differentiation via dephosphorylation of Kir2.1 K+ channels at tyrosine 242 , 2008, Development.
[58] J. I. Izpisúa Belmonte,et al. Bioelectricity and epimorphic regeneration. , 2007, BioEssays : news and reviews in molecular, cellular and developmental biology.
[59] M. Levin. Gap junctional communication in morphogenesis. , 2007, Progress in biophysics and molecular biology.
[60] Dany S. Adams,et al. H+ pump-dependent changes in membrane voltage are an early mechanism necessary and sufficient to induce Xenopus tail regeneration , 2007, Development.
[61] P. Lory,et al. Subunit‐specific modulation of T‐type calcium channels by zinc , 2007, The Journal of physiology.
[62] Melissa A. Wright,et al. Knockdown of Nav 1.6a Na+ channels affects zebrafish motoneuron development , 2006, Development.
[63] E. Vigmond,et al. Inward rectifying potassium channels facilitate cell-to-cell communication in hamster retractor muscle feed arteries. , 2006, American journal of physiology. Heart and circulatory physiology.
[64] Dany S. Adams,et al. Early, H+-V-ATPase-dependent proton flux is necessary for consistent left-right patterning of non-mammalian vertebrates , 2006, Development.
[65] M. Labouesse. Faculty Opinions recommendation of Early, H+-V-ATPase-dependent proton flux is necessary for consistent left-right patterning of non-mammalian vertebrates. , 2006 .
[66] Antonio Felipe,et al. Potassium channels: new targets in cancer therapy. , 2006, Cancer detection and prevention.
[67] M. Boyett,et al. A difference in inward rectification and polyamine block and permeation between the Kir2.1 and Kir3.1/Kir3.4 K+ channels , 2005, The Journal of physiology.
[68] Carol S. Woodward,et al. Enabling New Flexibility in the SUNDIALS Suite of Nonlinear and Differential/Algebraic Equation Solvers , 2020, ACM Trans. Math. Softw..
[69] Min Zhao,et al. Controlling cell behavior electrically: current views and future potential. , 2005, Physiological reviews.
[70] A. Ribera,et al. Developmental, molecular, and genetic dissection of INa in vivo in embryonic zebrafish sensory neurons. , 2005, Journal of neurophysiology.
[71] C. Bader,et al. Membrane Hyperpolarization Triggers Myogenin and Myocyte Enhancer Factor-2 Expression during Human Myoblast Differentiation* , 2004, Journal of Biological Chemistry.
[72] Chun-feng Shang,et al. Calcium influx through hyperpolarization-activated cation channels (I(h) channels) contributes to activity-evoked neuronal secretion. , 2004, Proceedings of the National Academy of Sciences of the United States of America.
[73] M. Bier,et al. A bistable membrane potential at low extracellular potassium concentration. , 2003, Biophysical chemistry.
[74] Richard Nuccitelli,et al. A role for endogenous electric fields in wound healing. , 2003, Current topics in developmental biology.
[75] M. Mercola,et al. Asymmetries in H+/K+-ATPase and Cell Membrane Potentials Comprise a Very Early Step in Left-Right Patterning , 2002, Cell.
[76] Wulfram Gerstner,et al. SPIKING NEURON MODELS Single Neurons , Populations , Plasticity , 2002 .
[77] Michael Häusser,et al. Membrane potential bistability is controlled by the hyperpolarization‐activated current IH in rat cerebellar Purkinje neurons in vitro , 2002, The Journal of physiology.
[78] J. Slack,et al. An amphibian with ambition: a new role for Xenopus in the 21st century , 2001, Genome Biology.
[79] Sulayman D. Dib-Hajj,et al. Nav1.3 Sodium Channels: Rapid Repriming and Slow Closed-State Inactivation Display Quantitative Differences after Expression in a Mammalian Cell Line and in Spinal Sensory Neurons , 2001, The Journal of Neuroscience.
[80] Asaf Keller,et al. Membrane Bistability in Olfactory Bulb Mitral Cells , 2001, The Journal of Neuroscience.
[81] M. Biel,et al. Cellular expression and functional characterization of four hyperpolarization-activated pacemaker channels in cardiac and neuronal tissues. , 2001, European journal of biochemistry.
[82] Shigeo Watanabe,et al. Low-threshold potassium channels and a low-threshold calcium channel regulate Ca2+ spike firing in the dendrites of cerebellar Purkinje neurons: a modeling study , 2001, Brain Research.
[83] A. Vinet. MEMORY AND BISTABILITY IN A ONE-DIMENSIONAL LOOP OF MODEL CARDIAC CELLS , 1999 .
[84] P R Montague,et al. Calcium dynamics in the extracellular space of mammalian neural tissue. , 1999, Biophysical journal.
[85] Nicholas W. Plummer,et al. Functional Analysis of the Mouse Scn8a Sodium Channel , 1998, The Journal of Neuroscience.
[86] B. Horowitz,et al. Molecular identification of a component of delayed rectifier current in gastrointestinal smooth muscles. , 1998, American journal of physiology. Gastrointestinal and liver physiology.
[87] D. Robinson,et al. Activation and inactivation properties of voltage-gated calcium currents in developing cat retinal ganglion cells , 1998, Neuroscience.
[88] S. O’Grady,et al. Effects of charybdotoxin on K+ channel (KV1.2) deactivation and inactivation kinetics. , 1996, European journal of pharmacology.
[89] L. Abbott,et al. Modeling state-dependent inactivation of membrane currents. , 1994, Biophysical journal.
[90] Shimon Marom. A note on bistability in a simple synapseless ‘point neuron’ model , 1994 .
[91] A. VanDongen,et al. Alteration and restoration of K+ channel function by deletions at the N- and C-termini , 1990, Neuron.
[92] J. Ruppersberg,et al. Cloning and expression of a human voltage‐gated potassium channel. A novel member of the RCK potassium channel family. , 1990, The EMBO journal.
[93] C. Stern. Electric fields in vertebrate repair by R. B. Borgens, K. R. Robinson, J. W. Vanable, Jr and M. E. McGinnis, Alan R. Liss, 1989. US$69.50 (310 pages) ISBN 0 8451 4274 7 , 1989, Trends in Neurosciences.
[94] B. Sakmann,et al. Molecular basis of functional diversity of voltage‐gated potassium channels in mammalian brain. , 1989, The EMBO journal.
[95] R. North,et al. Expression of a cloned rat brain potassium channel in Xenopus oocytes. , 1989, Science.
[96] R. Binggeli,et al. Membrane potentials and sodium channels: hypotheses for growth regulation and cancer formation based on changes in sodium channels and gap junctions. , 1986, Journal of theoretical biology.
[97] R. Woodruff,et al. Electrophoresis of proteins in intercellular bridges , 1980, Nature.
[98] Jaffe Lf. Control of development by ionic currents. , 1979 .
[99] L. Jaffe. Control of development by ionic currents. , 1979, Society of General Physiologists series.
[100] C. Cone. Variation of the transmembrane potential level as a basic mechanism of mitosis control. , 1970, Oncology.
[101] A. Hodgkin,et al. Currents carried by sodium and potassium ions through the membrane of the giant axon of Loligo , 1952, The Journal of physiology.
[102] A. Hodgkin,et al. The components of membrane conductance in the giant axon of Loligo , 1952, The Journal of physiology.
[103] Elmer Julius Lund,et al. Bioelectric fields and growth , 1947 .
[104] F. Northrop,et al. The Electro-Dynamic Theory of Life , 1935, The Quarterly Review of Biology.