High hydrostatic pressure induces slow contraction in mouse cardiomyocytes
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G. Iribe | K. Naruse | M. Nishiyama | Yohei Yamaguchi | Masatoshi Morimatsu | K. Kaihara | Toshiyuki Kaneko | H. Kai | Akira Takai | Keiko Kaihara
[1] Tomonobu M. Watanabe,et al. Pressure-induced changes on the morphology and gene expression in mammalian cells. , 2021, Biology open.
[2] Tomonobu M. Watanabe,et al. Glycine insertion modulates the fluorescence properties of Aequorea victoria green fluorescent protein and its variants in their ambient environment , 2021, Biophysics and physicobiology.
[3] L. Tobacman. TROPONIN REVEALED Uncovering the Structure of the Thin Filament On-Off Switch in Striated Muscle. , 2020, Biophysical journal.
[4] M. Nishiyama,et al. High hydrostatic pressure induces vigorous flagellar beating in Chlamydomonas non-motile mutants lacking the central apparatus , 2020, Scientific Reports.
[5] A. Kitao,et al. Molecular dynamics simulation of proteins under high pressure: Structure, function and thermodynamics. , 2020, Biochimica et biophysica acta. General subjects.
[6] H. Yanagisawa,et al. Cryo-EM structures of cardiac thin filaments reveal the 3D architecture of troponin , 2020, bioRxiv.
[7] Y. Hata,et al. Increased hydrostatic pressure induces nuclear translocation of DAF-16/FOXO in C. elegans. , 2020, Biochemical and biophysical research communications.
[8] K. Namba,et al. Cardiac muscle thin filament structures reveal calcium regulatory mechanism , 2020, Nature Communications.
[9] A. Kalli,et al. Force Sensing by Piezo Channels in Cardiovascular Health and Disease , 2019, Arteriosclerosis, thrombosis, and vascular biology.
[10] R. Winter. Interrogating the Structural Dynamics and Energetics of Biomolecular Systems with Pressure Modulation. , 2019, Annual review of biophysics.
[11] M. Williamson,et al. Characterization of low-lying excited states of proteins by high-pressure NMR. , 2019, Biochimica et biophysica acta. Proteins and proteomics.
[12] W. Herzog,et al. Single sarcomere contraction dynamics in a whole muscle , 2018, Scientific Reports.
[13] Y. Harada,et al. Commonly stabilized cytochromes c from deep-sea Shewanella and Pseudomonas , 2018, Bioscience, biotechnology, and biochemistry.
[14] Y. Yamaguchi,et al. TRPC3 participates in angiotensin II type 1 receptor-dependent stress-induced slow increase in intracellular Ca2+ concentration in mouse cardiomyocytes , 2018, The Journal of Physiological Sciences.
[15] M. Nishiyama. High-pressure microscopy for tracking dynamic properties of molecular machines. , 2017, Biophysical chemistry.
[16] C. Roumestand,et al. Monitoring protein folding through high pressure NMR spectroscopy. , 2017, Progress in nuclear magnetic resonance spectroscopy.
[17] Y. Yamaguchi,et al. Role of TRPC3 and TRPC6 channels in the myocardial response to stretch: Linking physiology and pathophysiology. , 2017, Progress in biophysics and molecular biology.
[18] G. Burnstock. Purinergic Signaling in the Cardiovascular System. , 2017, Circulation research.
[19] R. Allen,et al. Calcium Sensitive Fluorescent Dyes Fluo-4 and Fura Red under Pressure: Behaviour of Fluorescence and Buffer Properties under Hydrostatic Pressures up to 200 MPa , 2016, PloS one.
[20] V. Maupoil,et al. SarcOptiM for ImageJ: high-frequency online sarcomere length computing on stimulated cardiomyocytes. , 2016, American journal of physiology. Cell physiology.
[21] J. van der Velden,et al. Historical perspective on heart function: the Frank–Starling Law , 2015, Biophysical Reviews.
[22] L. Fassina,et al. Modulation of the Cardiomyocyte Contraction inside a Hydrostatic Pressure Bioreactor: In Vitro Verification of the Frank-Starling Law , 2015, BioMed research international.
[23] Kotaro Oyama,et al. Cardiac thin filament regulation and the Frank–Starling mechanism , 2014, The Journal of Physiological Sciences.
[24] D. Bers. Cardiac sarcoplasmic reticulum calcium leak: basis and roles in cardiac dysfunction. , 2014, Annual review of physiology.
[25] Donald M Bers,et al. Calcium movements inside the sarcoplasmic reticulum of cardiac myocytes. , 2013, Journal of molecular and cellular cardiology.
[26] S. Hitchcock-DeGregori,et al. Regulation of actin-myosin interaction by conserved periodic sites of tropomyosin , 2012, Proceedings of the National Academy of Sciences.
[27] S. Ishiwata,et al. Microscopic heat pulses induce contraction of cardiomyocytes without calcium transients. , 2012, Biochemical and biophysical research communications.
[28] Christopher W Ward,et al. X-ROS Signaling: Rapid Mechano-Chemo Transduction in Heart , 2011, Science.
[29] G. Iribe,et al. Effects of axial stretch on sarcolemmal BKCa channels in post‐hatch chick ventricular myocytes , 2010, Experimental physiology.
[30] P. Camelliti,et al. Axial Stretch of Rat Single Ventricular Cardiomyocytes Causes an Acute and Transient Increase in Ca2+ Spark Rate , 2009, Circulation research.
[31] Y. Nishiyama,et al. Pressure-induced changes in the structure and function of the kinesin-microtubule complex. , 2009, Biophysical journal.
[32] E. White,et al. The Frank–Starling mechanism in vertebrate cardiac myocytes , 2008, Journal of Experimental Biology.
[33] Lei Jin,et al. Cardiac thin filament regulation , 2008, Pflügers Archiv - European Journal of Physiology.
[34] T. Nishiumi,et al. Combined effects of high pressure and heat on shear value and histological characteristics of bovine skeletal muscle , 2007 .
[35] Yiming Wu,et al. Targeted deletion of titin N2B region leads to diastolic dysfunction and cardiac atrophy , 2007, Proceedings of the National Academy of Sciences.
[36] T. O’Connell,et al. Isolation and culture of adult mouse cardiac myocytes. , 2007, Methods in molecular biology.
[37] Shûhei Yamamoto,et al. Changes in the Immunogold Electron-Microscopic Localization of Calpain in Bovine Skeletal Muscle Induced by Conditioning and High-Pressure Treatment , 2006, Bioscience, biotechnology, and biochemistry.
[38] R. Fink,et al. 'In situ' high pressure confocal Ca(2+)-fluorescence microscopy in skeletal muscle: a new method to study pressure limits in mammalian cells. , 2006, Undersea & hyperbaric medicine : journal of the Undersea and Hyperbaric Medical Society, Inc.
[39] T. Irving,et al. Frank-Starling law of the heart and the cellular mechanisms of length-dependent activation , 2002, Pflügers Archiv.
[40] T. Iwasaki,et al. Effect of high hydrostatic pressure on chicken myosin subfragment-1. , 2002, International journal of biological macromolecules.
[41] D. Clark,et al. Pressure effects on intra- and intermolecular interactions within proteins. , 2002, Biochimica et biophysica acta.
[42] D. Bers. Cardiac excitation–contraction coupling , 2002, Nature.
[43] H. Granzier,et al. Titin-actin interaction in mouse myocardium: passive tension modulation and its regulation by calcium/S100A1. , 2001, Biophysical journal.
[44] D. Mattson,et al. Comparison of arterial blood pressure in different strains of mice. , 2001, American journal of hypertension.
[45] J. Silva,et al. Local heterogeneity in the pressure denaturation of the coiled-coil tropomyosin because of subdomain folding units. , 2001, Biochemistry.
[46] E. Homsher,et al. Regulation of contraction in striated muscle. , 2000, Physiological reviews.
[47] K. Ranatunga,et al. The influence of 2,3-butanedione 2-monoxime (BDM) on the interaction between actin and myosin in solution and in skinned muscle fibres , 1994, Journal of Muscle Research & Cell Motility.
[48] K. Ranatunga,et al. Contractile activation and force generation in skinned rabbit muscle fibres: effects of hydrostatic pressure. , 1994, The Journal of physiology.
[49] C. Herrmann,et al. Effect of 2,3-butanedione monoxime on myosin and myofibrillar ATPases. An example of an uncompetitive inhibitor. , 1992, Biochemistry.
[50] K. Ranatunga,et al. Changes produced by increased hydrostatic pressure in isometric contractions of rat fast muscle. , 1991, The Journal of physiology.
[51] M R Boyett,et al. The length, width and volume of isolated rat and ferret ventricular myocytes during twitch contractions and changes in osmotic strength , 1991, Experimental physiology.
[52] K. Ranatunga,et al. Hydrostatic compression in glycerinated rabbit muscle fibers. , 1990, Biophysical journal.
[53] W. L. Marshall,et al. Ion Product of Water Substance, 0-1000 C, 1-10,000 Bars. New International Formulation and Its Background, , 1981 .
[54] E. Salmon,et al. A new miniature hydrostatic pressure chamber for microscopy. Strain- free optical glass windows facilitate phase-contrast and polarized- light microscopy of living cells. Optional fixture permits simultaneous control of pressure and temperature , 1975, The Journal of cell biology.
[55] T. Ooi,et al. Effects of pressure on ATPase of myosin A, heavy meromyosin, and subfragment I. , 1971, Biochimica et biophysica acta.
[56] D. J. Edwards,et al. The action of pressure on the form of the electromyogram of auricle muscle , 1934 .
[57] M. Cattell,et al. REVERSAL OF THE STIMULATING ACTION OF HYDROSTATIC PRESSURE ON STRIATED MUSCLE , 1930, Science.
[58] M. Cattell,et al. THE STIMULATING ACTION OF HYDROSTATIC PRESSURE ON CARDIAC FUNCTION , 1928 .
[59] H. Matsuki,et al. High Pressure Bioscience , 2015, Subcellular Biochemistry.
[60] F. Buss,et al. Small-molecule inhibitors of myosin proteins. , 2013, Future medicinal chemistry.
[61] J. Feher. The Cellular Basis of Cardiac Contractility , 2012 .
[62] F. Duprat,et al. Sensing pressure in the cardiovascular system: Gq-coupled mechanoreceptors and TRP channels. , 2010, Journal of molecular and cellular cardiology.
[63] G. O'Neill,et al. Tropomyosin-based regulation of the actin cytoskeleton in time and space. , 2008, Physiological reviews.
[64] M. Kellermayer,et al. Stretching and visualizing titin molecules: combining structure, dynamics and mechanics , 2004, Journal of Muscle Research & Cell Motility.
[65] Wolfgang A. Linke,et al. Cardiac titin: molecular basis of elasticity and cellular contribution to elastic and viscous stiffness components in myocardium , 2004, Journal of Muscle Research & Cell Motility.
[66] R. Fink,et al. Reversibility of high pressure effects on the contractility of skeletal muscle , 2004, Journal of Muscle Research & Cell Motility.
[67] H. Granzier,et al. Titin as a modular spring: emerging mechanisms for elasticity control by titin in cardiac physiology and pathophysiology. , 2002, Journal of muscle research and cell motility.
[68] A. Macdonald. Effects of High Pressure on Biological Systems , 1993, Advances in Comparative and Environmental Physiology.
[69] S. Besch,et al. Vertebrate Skeletal and Cardiac Muscle , 1993 .