- ↑
Miyawaki, A., Llopis, J., Heim, R., McCaffery, J.M., Adams, J.A., Ikura, M., & Tsien, R.Y. (1997).
Fluorescent indicators for Ca2+ based on green fluorescent proteins and calmodulin. Nature, 388(6645), 882-7. [PubMed:9278050] [WorldCat] [DOI] - ↑
Sato, M., Hida, N., Ozawa, T., & Umezawa, Y. (2000).
Fluorescent indicators for cyclic GMP based on cyclic GMP-dependent protein kinase Ialpha and green fluorescent proteins. Analytical chemistry, 72(24), 5918-24. [PubMed:11140757] [WorldCat] [DOI] - ↑
Honda, A., Adams, S.R., Sawyer, C.L., Lev-Ram, V., Tsien, R.Y., & Dostmann, W.R. (2001).
Spatiotemporal dynamics of guanosine 3',5'-cyclic monophosphate revealed by a genetically encoded, fluorescent indicator. Proceedings of the National Academy of Sciences of the United States of America, 98(5), 2437-42. [PubMed:11226257] [PMC] [WorldCat] [DOI] - ↑
Nikolaev, V.O., Gambaryan, S., & Lohse, M.J. (2006).
Fluorescent sensors for rapid monitoring of intracellular cGMP. Nature methods, 3(1), 23-5. [PubMed:16369548] [WorldCat] [DOI] - ↑
Zaccolo, M., & Pozzan, T. (2002).
Discrete microdomains with high concentration of cAMP in stimulated rat neonatal cardiac myocytes. Science (New York, N.Y.), 295(5560), 1711-5. [PubMed:11872839] [WorldCat] [DOI] - ↑
Nikolaev, V.O., Bünemann, M., Hein, L., Hannawacker, A., & Lohse, M.J. (2004).
Novel single chain cAMP sensors for receptor-induced signal propagation. The Journal of biological chemistry, 279(36), 37215-8. [PubMed:15231839] [WorldCat] [DOI] - ↑
Tanimura, A., Nezu, A., Morita, T., Turner, R.J., & Tojyo, Y. (2004).
Fluorescent biosensor for quantitative real-time measurements of inositol 1,4,5-trisphosphate in single living cells. The Journal of biological chemistry, 279(37), 38095-8. [PubMed:15272011] [WorldCat] [DOI] - ↑
Sato, M., Ueda, Y., Shibuya, M., & Umezawa, Y. (2005).
Locating inositol 1,4,5-trisphosphate in the nucleus and neuronal dendrites with genetically encoded fluorescent indicators. Analytical chemistry, 77(15), 4751-8. [PubMed:16053285] [WorldCat] [DOI] - ↑
Matsu-ura, T., Michikawa, T., Inoue, T., Miyawaki, A., Yoshida, M., & Mikoshiba, K. (2006).
Cytosolic inositol 1,4,5-trisphosphate dynamics during intracellular calcium oscillations in living cells. The Journal of cell biology, 173(5), 755-65. [PubMed:16754959] [PMC] [WorldCat] [DOI] - ↑
Sato, M., Hida, N., & Umezawa, Y. (2005).
Imaging the nanomolar range of nitric oxide with an amplifier-coupled fluorescent indicator in living cells. Proceedings of the National Academy of Sciences of the United States of America, 102(41), 14515-20. [PubMed:16176986] [PMC] [WorldCat] [DOI] - ↑
Sato, M., Nakajima, T., Goto, M., & Umezawa, Y. (2006).
Cell-based indicator to visualize picomolar dynamics of nitric oxide release from living cells. Analytical chemistry, 78(24), 8175-82. [PubMed:17165805] [WorldCat] [DOI] - ↑
Imamura, H., Nhat, K.P., Togawa, H., Saito, K., Iino, R., Kato-Yamada, Y., ..., & Noji, H. (2009).
Visualization of ATP levels inside single living cells with fluorescence resonance energy transfer-based genetically encoded indicators. Proceedings of the National Academy of Sciences of the United States of America, 106(37), 15651-6. [PubMed:19720993] [PMC] [WorldCat] [DOI] - ↑
Awais, M., Sato, M., Sasaki, K., & Umezawa, Y. (2004).
A genetically encoded fluorescent indicator capable of discriminating estrogen agonists from antagonists in living cells. Analytical chemistry, 76(8), 2181-6. [PubMed:15080726] [WorldCat] [DOI] - ↑
Awais, M., Sato, M., Lee, X., & Umezawa, Y. (2006).
A fluorescent indicator to visualize activities of the androgen receptor ligands in single living cells. Angewandte Chemie (International ed. in English), 45(17), 2707-12. [PubMed:16555356] [WorldCat] [DOI] - ↑
Awais, M., Sato, M., & Umezawa, Y. (2007).
Optical probes to identify the glucocorticoid receptor ligands in living cells. Steroids, 72(14), 949-54. [PubMed:17897691] [WorldCat] [DOI] - ↑
Nakajima, T., Sato, M., Akaza, N., & Umezawa, Y. (2008).
Cell-based fluorescent indicator to visualize brain-derived neurotrophic factor secreted from living neurons. ACS chemical biology, 3(6), 352-8. [PubMed:18510313] [WorldCat] [DOI] - ↑
Awais, M., Sato, M., & Umezawa, Y. (2007).
Imaging of selective nuclear receptor modulator-induced conformational changes in the nuclear receptor to allow interaction with coactivator and corepressor proteins in living cells. Chembiochem : a European journal of chemical biology, 8(7), 737-43. [PubMed:17387660] [WorldCat] [DOI] - ↑
Carrillo, L.D., Krishnamoorthy, L., & Mahal, L.K. (2006).
A cellular FRET-based sensor for beta-O-GlcNAc, a dynamic carbohydrate modification involved in signaling. Journal of the American Chemical Society, 128(46), 14768-9. [PubMed:17105262] [WorldCat] [DOI] - ↑
Shimozono, S., Iimura, T., Kitaguchi, T., Higashijima, S., & Miyawaki, A. (2013).
Visualization of an endogenous retinoic acid gradient across embryonic development. Nature, 496(7445), 363-6. [PubMed:23563268] [WorldCat] [DOI] - ↑
Nakanishi, Y., Iida, S., Ueoka-Nakanishi, H., Niimi, T., Tomioka, R., & Maeshima, M. (2013).
Exploring dynamics of molybdate in living animal cells by a genetically encoded FRET nanosensor. PloS one, 8(3), e58175. [PubMed:23472155] [PMC] [WorldCat] [DOI] - ↑
Okumoto, S., Looger, L.L., Micheva, K.D., Reimer, R.J., Smith, S.J., & Frommer, W.B. (2005).
Detection of glutamate release from neurons by genetically encoded surface-displayed FRET nanosensors. Proceedings of the National Academy of Sciences of the United States of America, 102(24), 8740-5. [PubMed:15939876] [PMC] [WorldCat] [DOI] - ↑
Vinkenborg, J.L., Nicolson, T.J., Bellomo, E.A., Koay, M.S., Rutter, G.A., & Merkx, M. (2009).
Genetically encoded FRET sensors to monitor intracellular Zn2+ homeostasis. Nature methods, 6(10), 737-40. [PubMed:19718032] [PMC] [WorldCat] [DOI] - ↑
Kuner, T., & Augustine, G.J. (2000).
A genetically encoded ratiometric indicator for chloride: capturing chloride transients in cultured hippocampal neurons. Neuron, 27(3), 447-59. [PubMed:11055428] [WorldCat] [DOI] - ↑
Awaji, T., Hirasawa, A., Shirakawa, H., Tsujimoto, G., & Miyazaki, S. (2001).
Novel green fluorescent protein-based ratiometric indicators for monitoring pH in defined intracellular microdomains. Biochemical and biophysical research communications, 289(2), 457-62. [PubMed:11716495] [WorldCat] [DOI] - ↑
Fehr, M., Lalonde, S., Lager, I., Wolff, M.W., & Frommer, W.B. (2003).
In vivo imaging of the dynamics of glucose uptake in the cytosol of COS-7 cells by fluorescent nanosensors. The Journal of biological chemistry, 278(21), 19127-33. [PubMed:12649277] [WorldCat] [DOI] - ↑
Fehr, M., Frommer, W.B., & Lalonde, S. (2002).
Visualization of maltose uptake in living yeast cells by fluorescent nanosensors. Proceedings of the National Academy of Sciences of the United States of America, 99(15), 9846-51. [PubMed:12097642] [PMC] [WorldCat] [DOI] - ↑
Lager, I., Fehr, M., Frommer, W.B., & Lalonde, S. (2003).
Development of a fluorescent nanosensor for ribose. FEBS letters, 553(1-2), 85-9. [PubMed:14550551] [WorldCat] [DOI] - ↑
Takao, K., Okamoto, K., Nakagawa, T., Neve, R.L., Nagai, T., Miyawaki, A., ..., & Hayashi, Y. (2005).
Visualization of synaptic Ca2+ /calmodulin-dependent protein kinase II activity in living neurons. The Journal of neuroscience : the official journal of the Society for Neuroscience, 25(12), 3107-12. [PubMed:15788767] [PMC] [WorldCat] [DOI] - ↑
Lee, S.J., Escobedo-Lozoya, Y., Szatmari, E.M., & Yasuda, R. (2009).
Activation of CaMKII in single dendritic spines during long-term potentiation. Nature, 458(7236), 299-304. [PubMed:19295602] [PMC] [WorldCat] [DOI] - ↑
Fujii, H., Inoue, M., Okuno, H., Sano, Y., Takemoto-Kimura, S., Kitamura, K., ..., & Bito, H. (2013).
Nonlinear decoding and asymmetric representation of neuronal input information by CaMKIIα and calcineurin. Cell reports, 3(4), 978-87. [PubMed:23602566] [WorldCat] [DOI] - ↑
Piljić, A., de Diego, I., Wilmanns, M., & Schultz, C. (2011).
Rapid development of genetically encoded FRET reporters. ACS chemical biology, 6(7), 685-91. [PubMed:21506563] [WorldCat] [DOI] - ↑
Ting, A.Y., Kain, K.H., Klemke, R.L., & Tsien, R.Y. (2001).
Genetically encoded fluorescent reporters of protein tyrosine kinase activities in living cells. Proceedings of the National Academy of Sciences of the United States of America, 98(26), 15003-8. [PubMed:11752449] [PMC] [WorldCat] [DOI] - ↑
Wang, Y., Botvinick, E.L., Zhao, Y., Berns, M.W., Usami, S., Tsien, R.Y., & Chien, S. (2005).
Visualizing the mechanical activation of Src. Nature, 434(7036), 1040-5. [PubMed:15846350] [WorldCat] [DOI] - ↑
Hitosugi, T., Sasaki, K., Sato, M., Suzuki, Y., & Umezawa, Y. (2007).
Epidermal growth factor directs sex-specific steroid signaling through Src activation. The Journal of biological chemistry, 282(14), 10697-706. [PubMed:17284441] [WorldCat] [DOI] - ↑
Violin, J.D., Zhang, J., Tsien, R.Y., & Newton, A.C. (2003).
A genetically encoded fluorescent reporter reveals oscillatory phosphorylation by protein kinase C. The Journal of cell biology, 161(5), 899-909. [PubMed:12782683] [PMC] [WorldCat] [DOI] - ↑
Braun, D.C., Garfield, S.H., & Blumberg, P.M. (2005).
Analysis by fluorescence resonance energy transfer of the interaction between ligands and protein kinase Cdelta in the intact cell. The Journal of biological chemistry, 280(9), 8164-71. [PubMed:15611119] [WorldCat] [DOI] - ↑
Kunkel, M.T., Toker, A., Tsien, R.Y., & Newton, A.C. (2007).
Calcium-dependent regulation of protein kinase D revealed by a genetically encoded kinase activity reporter. The Journal of biological chemistry, 282(9), 6733-42. [PubMed:17189263] [PMC] [WorldCat] [DOI] - ↑
Nagai, Y., Miyazaki, M., Aoki, R., Zama, T., Inouye, S., Hirose, K., ..., & Hagiwara, M. (2000).
A fluorescent indicator for visualizing cAMP-induced phosphorylation in vivo. Nature biotechnology, 18(3), 313-6. [PubMed:10700148] [WorldCat] [DOI]
Zhang, J., Ma, Y., Taylor, S.S., & Tsien, R.Y. (2001).
Genetically encoded reporters of protein kinase A activity reveal impact of substrate tethering. Proceedings of the National Academy of Sciences of the United States of America, 98(26), 14997-5002. [PubMed:11752448] [PMC] [WorldCat] [DOI] - ↑
Ting, A.Y., Kain, K.H., Klemke, R.L., & Tsien, R.Y. (2001).
Genetically encoded fluorescent reporters of protein tyrosine kinase activities in living cells. Proceedings of the National Academy of Sciences of the United States of America, 98(26), 15003-8. [PubMed:11752449] [PMC] [WorldCat] [DOI] - ↑
Tunceroglu, A., Matsuda, M., & Birge, R.B. (2010).
Real-time fluorescent resonance energy transfer analysis to monitor drug resistance in chronic myelogenous leukemia. Molecular cancer therapeutics, 9(11), 3065-73. [PubMed:20817824] [PMC] [WorldCat] [DOI] - ↑
Terai, K., & Matsuda, M. (2005).
Ras binding opens c-Raf to expose the docking site for mitogen-activated protein kinase kinase. EMBO reports, 6(3), 251-5. [PubMed:15711535] [PMC] [WorldCat] [DOI] - ↑
Parrini, M.C., Camonis, J., Matsuda, M., & de Gunzburg, J. (2009).
Dissecting activation of the PAK1 kinase at protrusions in living cells. The Journal of biological chemistry, 284(36), 24133-43. [PubMed:19574218] [PMC] [WorldCat] [DOI] - ↑
Terai, K., & Matsuda, M. (2006).
The amino-terminal B-Raf-specific region mediates calcium-dependent homo- and hetero-dimerization of Raf. The EMBO journal, 25(15), 3556-64. [PubMed:16858395] [PMC] [WorldCat] [DOI] - ↑
Randriamampita, C., Mouchacca, P., Malissen, B., Marguet, D., Trautmann, A., & Lellouch, A.C. (2008).
A novel ZAP-70 dependent FRET based biosensor reveals kinase activity at both the immunological synapse and the antisynapse. PloS one, 3(1), e1521. [PubMed:18231606] [PMC] [WorldCat] [DOI] - ↑
Sasaki, K., Sato, M., & Umezawa, Y. (2003).
Fluorescent indicators for Akt/protein kinase B and dynamics of Akt activity visualized in living cells. The Journal of biological chemistry, 278(33), 30945-51. [PubMed:12773546] [WorldCat] [DOI] - ↑
Kunkel, M.T., Ni, Q., Tsien, R.Y., Zhang, J., & Newton, A.C. (2005).
Spatio-temporal dynamics of protein kinase B/Akt signaling revealed by a genetically encoded fluorescent reporter. The Journal of biological chemistry, 280(7), 5581-7. [PubMed:15583002] [PMC] [WorldCat] [DOI] - ↑
Calleja, V., Alcor, D., Laguerre, M., Park, J., Vojnovic, B., Hemmings, B.A., ..., & Larijani, B. (2007).
Intramolecular and intermolecular interactions of protein kinase B define its activation in vivo. PLoS biology, 5(4), e95. [PubMed:17407381] [PMC] [WorldCat] [DOI] - ↑
Fujioka, A., Terai, K., Itoh, R.E., Aoki, K., Nakamura, T., Kuroda, S., ..., & Matsuda, M. (2006).
Dynamics of the Ras/ERK MAPK cascade as monitored by fluorescent probes. The Journal of biological chemistry, 281(13), 8917-26. [PubMed:16418172] [WorldCat] [DOI] - ↑
Sato, M., Kawai, Y., & Umezawa, Y. (2007).
Genetically encoded fluorescent indicators to visualize protein phosphorylation by extracellular signal-regulated kinase in single living cells. Analytical chemistry, 79(6), 2570-5. [PubMed:17261026] [WorldCat] [DOI] - ↑
Harvey, C.D., Ehrhardt, A.G., Cellurale, C., Zhong, H., Yasuda, R., Davis, R.J., & Svoboda, K. (2008).
A genetically encoded fluorescent sensor of ERK activity. Proceedings of the National Academy of Sciences of the United States of America, 105(49), 19264-9. [PubMed:19033456] [PMC] [WorldCat] [DOI] - ↑
Sato, M., Ozawa, T., Inukai, K., Asano, T., & Umezawa, Y. (2002).
Fluorescent indicators for imaging protein phosphorylation in single living cells. Nature biotechnology, 20(3), 287-94. [PubMed:11875431] [WorldCat] [DOI] - ↑
Ting, A.Y., Kain, K.H., Klemke, R.L., & Tsien, R.Y. (2001).
Genetically encoded fluorescent reporters of protein tyrosine kinase activities in living cells. Proceedings of the National Academy of Sciences of the United States of America, 98(26), 15003-8. [PubMed:11752449] [PMC] [WorldCat] [DOI] - ↑
Johnson, S.A., You, Z., & Hunter, T. (2007).
Monitoring ATM kinase activity in living cells. DNA repair, 6(9), 1277-84. [PubMed:17428747] [WorldCat] [DOI] - ↑
Fuller, B.G., Lampson, M.A., Foley, E.A., Rosasco-Nitcher, S., Le, K.V., Tobelmann, P., ..., & Kapoor, T.M. (2008).
Midzone activation of aurora B in anaphase produces an intracellular phosphorylation gradient. Nature, 453(7198), 1132-6. [PubMed:18463638] [PMC] [WorldCat] [DOI] - ↑
Gavet, O., & Pines, J. (2010).
Progressive activation of CyclinB1-Cdk1 coordinates entry to mitosis. Developmental cell, 18(4), 533-43. [PubMed:20412769] [PMC] [WorldCat] [DOI] - ↑
Chew, T.L., Wolf, W.A., Gallagher, P.J., Matsumura, F., & Chisholm, R.L. (2002).
A fluorescent resonant energy transfer-based biosensor reveals transient and regional myosin light chain kinase activation in lamella and cleavage furrows. The Journal of cell biology, 156(3), 543-53. [PubMed:11815633] [PMC] [WorldCat] [DOI] - ↑
Fosbrink, M., Aye-Han, N.N., Cheong, R., Levchenko, A., & Zhang, J. (2010).
Visualization of JNK activity dynamics with a genetically encoded fluorescent biosensor. Proceedings of the National Academy of Sciences of the United States of America, 107(12), 5459-64. [PubMed:20212108] [PMC] [WorldCat] [DOI] - ↑
Komatsu, N., Aoki, K., Yamada, M., Yukinaga, H., Fujita, Y., Kamioka, Y., & Matsuda, M. (2011).
Development of an optimized backbone of FRET biosensors for kinases and GTPases. Molecular biology of the cell, 22(23), 4647-56. [PubMed:21976697] [PMC] [WorldCat] [DOI] - ↑
Komatsu, N., Aoki, K., Yamada, M., Yukinaga, H., Fujita, Y., Kamioka, Y., & Matsuda, M. (2011).
Development of an optimized backbone of FRET biosensors for kinases and GTPases. Molecular biology of the cell, 22(23), 4647-56. [PubMed:21976697] [PMC] [WorldCat] [DOI] - ↑
Komatsu, N., Aoki, K., Yamada, M., Yukinaga, H., Fujita, Y., Kamioka, Y., & Matsuda, M. (2011).
Development of an optimized backbone of FRET biosensors for kinases and GTPases. Molecular biology of the cell, 22(23), 4647-56. [PubMed:21976697] [PMC] [WorldCat] [DOI] - ↑
Cai, X., Lietha, D., Ceccarelli, D.F., Karginov, A.V., Rajfur, Z., Jacobson, K., ..., & Schaller, M.D. (2008).
Spatial and temporal regulation of focal adhesion kinase activity in living cells. Molecular and cellular biology, 28(1), 201-14. [PubMed:17967873] [PMC] [WorldCat] [DOI] - ↑
Papusheva, E., Mello de Queiroz, F., Dalous, J., Han, Y., Esposito, A., Jares-Erijmanxa, E.A., ..., & Bunt, G. (2009).
Dynamic conformational changes in the FERM domain of FAK are involved in focal-adhesion behavior during cell spreading and motility. Journal of cell science, 122(Pt 5), 656-66. [PubMed:19208768] [WorldCat] [DOI] - ↑
Macůrek, L., Lindqvist, A., Lim, D., Lampson, M.A., Klompmaker, R., Freire, R., ..., & Medema, R.H. (2008).
Polo-like kinase-1 is activated by aurora A to promote checkpoint recovery. Nature, 455(7209), 119-23. [PubMed:18615013] [WorldCat] [DOI] - ↑
Tomida, T., Takekawa, M., O'Grady, P., & Saito, H. (2009).
Stimulus-specific distinctions in spatial and temporal dynamics of stress-activated protein kinase kinase kinases revealed by a fluorescence resonance energy transfer biosensor. Molecular and cellular biology, 29(22), 6117-27. [PubMed:19737916] [PMC] [WorldCat] [DOI] - ↑
Piljić, A., de Diego, I., Wilmanns, M., & Schultz, C. (2011).
Rapid development of genetically encoded FRET reporters. ACS chemical biology, 6(7), 685-91. [PubMed:21506563] [WorldCat] [DOI] - ↑
Fujii, H., Inoue, M., Okuno, H., Sano, Y., Takemoto-Kimura, S., Kitamura, K., ..., & Bito, H. (2013).
Nonlinear decoding and asymmetric representation of neuronal input information by CaMKIIα and calcineurin. Cell reports, 3(4), 978-87. [PubMed:23602566] [WorldCat] [DOI] - ↑
Newman, R.H., & Zhang, J. (2008).
Visualization of phosphatase activity in living cells with a FRET-based calcineurin activity sensor. Molecular bioSystems, 4(6), 496-501. [PubMed:18493642] [WorldCat] [DOI] - ↑
Yasuda, R., Harvey, C.D., Zhong, H., Sobczyk, A., van Aelst, L., & Svoboda, K. (2006).
Supersensitive Ras activation in dendrites and spines revealed by two-photon fluorescence lifetime imaging. Nature neuroscience, 9(2), 283-91. [PubMed:16429133] [WorldCat] [DOI] - ↑
Mochizuki, N., Yamashita, S., Kurokawa, K., Ohba, Y., Nagai, T., Miyawaki, A., & Matsuda, M. (2001).
Spatio-temporal images of growth-factor-induced activation of Ras and Rap1. Nature, 411(6841), 1065-8. [PubMed:11429608] [WorldCat] [DOI] - ↑
Mochizuki, N., Yamashita, S., Kurokawa, K., Ohba, Y., Nagai, T., Miyawaki, A., & Matsuda, M. (2001).
Spatio-temporal images of growth-factor-induced activation of Ras and Rap1. Nature, 411(6841), 1065-8. [PubMed:11429608] [WorldCat] [DOI] - ↑
Aoki, K., Nakamura, T., & Matsuda, M. (2004).
Spatio-temporal regulation of Rac1 and Cdc42 activity during nerve growth factor-induced neurite outgrowth in PC12 cells. The Journal of biological chemistry, 279(1), 713-9. [PubMed:14570905] [WorldCat] [DOI] - ↑
Kitano, M., Nakaya, M., Nakamura, T., Nagata, S., & Matsuda, M. (2008).
Imaging of Rab5 activity identifies essential regulators for phagosome maturation. Nature, 453(7192), 241-5. [PubMed:18385674] [WorldCat] [DOI] - ↑
Murakoshi, H., Wang, H., & Yasuda, R. (2011).
Local, persistent activation of Rho GTPases during plasticity of single dendritic spines. Nature, 472(7341), 100-4. [PubMed:21423166] [PMC] [WorldCat] [DOI] - ↑
Yoshizaki, H., Ohba, Y., Kurokawa, K., Itoh, R.E., Nakamura, T., Mochizuki, N., ..., & Matsuda, M. (2003).
Activity of Rho-family GTPases during cell division as visualized with FRET-based probes. The Journal of cell biology, 162(2), 223-32. [PubMed:12860967] [PMC] [WorldCat] [DOI] - ↑
Aoki, K., Nakamura, T., & Matsuda, M. (2004).
Spatio-temporal regulation of Rac1 and Cdc42 activity during nerve growth factor-induced neurite outgrowth in PC12 cells. The Journal of biological chemistry, 279(1), 713-9. [PubMed:14570905] [WorldCat] [DOI] - ↑
Murakoshi, H., Wang, H., & Yasuda, R. (2011).
Local, persistent activation of Rho GTPases during plasticity of single dendritic spines. Nature, 472(7341), 100-4. [PubMed:21423166] [PMC] [WorldCat] [DOI] - ↑
Takaya, A., Ohba, Y., Kurokawa, K., & Matsuda, M. (2004).
RalA activation at nascent lamellipodia of epidermal growth factor-stimulated Cos7 cells and migrating Madin-Darby canine kidney cells. Molecular biology of the cell, 15(6), 2549-57. [PubMed:15034142] [PMC] [WorldCat] [DOI] - ↑
Kawase, K., Nakamura, T., Takaya, A., Aoki, K., Namikawa, K., Kiyama, H., ..., & Matsuda, M. (2006).
GTP hydrolysis by the Rho family GTPase TC10 promotes exocytic vesicle fusion. Developmental cell, 11(3), 411-21. [PubMed:16950130] [WorldCat] [DOI] - ↑
Hao, Y., & Macara, I.G. (2008).
Regulation of chromatin binding by a conformational switch in the tail of the Ran exchange factor RCC1. The Journal of cell biology, 182(5), 827-36. [PubMed:18762580] [PMC] [WorldCat] [DOI] - ↑
Kurokawa, K., Mochizuki, N., Ohba, Y., Mizuno, H., Miyawaki, A., & Matsuda, M. (2001).
A pair of fluorescent resonance energy transfer-based probes for tyrosine phosphorylation of the CrkII adaptor protein in vivo. The Journal of biological chemistry, 276(33), 31305-10. [PubMed:11406630] [WorldCat] [DOI] - ↑
Lorenz, M., Yamaguchi, H., Wang, Y., Singer, R.H., & Condeelis, J. (2004).
Imaging sites of N-wasp activity in lamellipodia and invadopodia of carcinoma cells. Current biology : CB, 14(8), 697-703. [PubMed:15084285] [WorldCat] [DOI] - ↑
Ward, M.E., Wu, J.Y., & Rao, Y. (2004).
Visualization of spatially and temporally regulated N-WASP activity during cytoskeletal reorganization in living cells. Proceedings of the National Academy of Sciences of the United States of America, 101(4), 970-4. [PubMed:14732696] [PMC] [WorldCat] [DOI] - ↑
Vilardaga, J.P., Bünemann, M., Krasel, C., Castro, M., & Lohse, M.J. (2003).
Measurement of the millisecond activation switch of G protein-coupled receptors in living cells. Nature biotechnology, 21(7), 807-12. [PubMed:12808462] [WorldCat] [DOI] - ↑
Vilardaga, J.P., Bünemann, M., Krasel, C., Castro, M., & Lohse, M.J. (2003).
Measurement of the millisecond activation switch of G protein-coupled receptors in living cells. Nature biotechnology, 21(7), 807-12. [PubMed:12808462] [WorldCat] [DOI] - ↑
Corradi, G.R., & Adamo, H.P. (2007).
Intramolecular fluorescence resonance energy transfer between fused autofluorescent proteins reveals rearrangements of the N- and C-terminal segments of the plasma membrane Ca2+ pump involved in the activation. The Journal of biological chemistry, 282(49), 35440-8. [PubMed:17901055] [WorldCat] [DOI] - ↑
Lin, C.W., Jao, C.Y., & Ting, A.Y. (2004).
Genetically encoded fluorescent reporters of histone methylation in living cells. Journal of the American Chemical Society, 126(19), 5982-3. [PubMed:15137760] [WorldCat] [DOI] - ↑
Sasaki, K., Ito, T., Nishino, N., Khochbin, S., & Yoshida, M. (2009).
Real-time imaging of histone H4 hyperacetylation in living cells. Proceedings of the National Academy of Sciences of the United States of America, 106(38), 16257-62. [PubMed:19805290] [PMC] [WorldCat] [DOI] - ↑
Sato, M., Ueda, Y., Takagi, T., & Umezawa, Y. (2003).
Production of PtdInsP3 at endomembranes is triggered by receptor endocytosis. Nature cell biology, 5(11), 1016-22. [PubMed:14528311] [WorldCat] [DOI] - ↑
Nishioka, T., Aoki, K., Hikake, K., Yoshizaki, H., Kiyokawa, E., & Matsuda, M. (2008).
Rapid turnover rate of phosphoinositides at the front of migrating MDCK cells. Molecular biology of the cell, 19(10), 4213-23. [PubMed:18685081] [PMC] [WorldCat] [DOI] - ↑
Nishioka, T., Aoki, K., Hikake, K., Yoshizaki, H., Kiyokawa, E., & Matsuda, M. (2008).
Rapid turnover rate of phosphoinositides at the front of migrating MDCK cells. Molecular biology of the cell, 19(10), 4213-23. [PubMed:18685081] [PMC] [WorldCat] [DOI] - ↑
Nishioka, T., Aoki, K., Hikake, K., Yoshizaki, H., Kiyokawa, E., & Matsuda, M. (2008).
Rapid turnover rate of phosphoinositides at the front of migrating MDCK cells. Molecular biology of the cell, 19(10), 4213-23. [PubMed:18685081] [PMC] [WorldCat] [DOI] - ↑
Nishioka, T., Frohman, M.A., Matsuda, M., & Kiyokawa, E. (2010).
Heterogeneity of phosphatidic acid levels and distribution at the plasma membrane in living cells as visualized by a Föster resonance energy transfer (FRET) biosensor. The Journal of biological chemistry, 285(46), 35979-87. [PubMed:20826779] [PMC] [WorldCat] [DOI] - ↑
Nishioka, T., Aoki, K., Hikake, K., Yoshizaki, H., Kiyokawa, E., & Matsuda, M. (2008).
Rapid turnover rate of phosphoinositides at the front of migrating MDCK cells. Molecular biology of the cell, 19(10), 4213-23. [PubMed:18685081] [PMC] [WorldCat] [DOI] - ↑
Sato, M., Ueda, Y., & Umezawa, Y. (2006).
Imaging diacylglycerol dynamics at organelle membranes. Nature methods, 3(10), 797-9. [PubMed:16990811] [WorldCat] [DOI] - ↑
Okamoto, K., Nagai, T., Miyawaki, A., & Hayashi, Y. (2004).
Rapid and persistent modulation of actin dynamics regulates postsynaptic reorganization underlying bidirectional plasticity. Nature neuroscience, 7(10), 1104-12. [PubMed:15361876] [WorldCat] [DOI] - ↑
Murakoshi, H., Lee, S.J., & Yasuda, R. (2008).
Highly sensitive and quantitative FRET-FLIM imaging in single dendritic spines using improved non-radiative YFP. Brain cell biology, 36(1-4), 31-42. [PubMed:18512154] [PMC] [WorldCat] [DOI] - ↑
Calleja, V., Alcor, D., Laguerre, M., Park, J., Vojnovic, B., Hemmings, B.A., ..., & Larijani, B. (2007).
Intramolecular and intermolecular interactions of protein kinase B define its activation in vivo. PLoS biology, 5(4), e95. [PubMed:17407381] [PMC] [WorldCat] [DOI] - ↑
Haj, F.G., Verveer, P.J., Squire, A., Neel, B.G., & Bastiaens, P.I. (2002).
Imaging sites of receptor dephosphorylation by PTP1B on the surface of the endoplasmic reticulum. Science (New York, N.Y.), 295(5560), 1708-11. [PubMed:11872838] [WorldCat] [DOI] - ↑
Ni, Z., Mark, M.E., Cai, X., & Mao, Q. (2010).
Fluorescence resonance energy transfer (FRET) analysis demonstrates dimer/oligomer formation of the human breast cancer resistance protein (BCRP/ABCG2) in intact cells. International journal of biochemistry and molecular biology, 1(1), 1-11. [PubMed:20622991] [PMC] [WorldCat] - ↑
Homma, K., Niino, Y., Hotta, K., & Oka, K. (2008).
Ca(2+) influx through P2X receptors induces actin cytoskeleton reorganization by the formation of cofilin rods in neurites. Molecular and cellular neurosciences, 37(2), 261-70. [PubMed:17993279] [WorldCat] [DOI] - ↑
van Diepen, M.T., Parsons, M., Downes, C.P., Leslie, N.R., Hindges, R., & Eickholt, B.J. (2009).
MyosinV controls PTEN function and neuronal cell size. Nature cell biology, 11(10), 1191-6. [PubMed:19767745] [PMC] [WorldCat] [DOI] - ↑
Xu, X., Gerard, A.L., Huang, B.C., Anderson, D.C., Payan, D.G., & Luo, Y. (1998).
Detection of programmed cell death using fluorescence energy transfer. Nucleic acids research, 26(8), 2034-5. [PubMed:9518501] [PMC] [WorldCat] [DOI] - ↑
Onuki, R., Nagasaki, A., Kawasaki, H., Baba, T., Uyeda, T.Q., & Taira, K. (2002).
Confirmation by FRET in individual living cells of the absence of significant amyloid beta -mediated caspase 8 activation. Proceedings of the National Academy of Sciences of the United States of America, 99(23), 14716-21. [PubMed:12409609] [PMC] [WorldCat] [DOI] - ↑
Joseph, J., Seervi, M., Sobhan, P.K., & Retnabai, S.T. (2011).
High throughput ratio imaging to profile caspase activity: potential application in multiparameter high content apoptosis analysis and drug screening. PloS one, 6(5), e20114. [PubMed:21637712] [PMC] [WorldCat] [DOI] - ↑
Li, I.T., Chiang, J.J., & Truong, K. (2006).
FRET evidence that an isoform of caspase-7 binds but does not cleave its substrate. Conference proceedings : ... Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual Conference, 1, 531-4. [PubMed:17946841] [WorldCat] [DOI] - ↑
Yang, J., Zhang, Z., Lin, J., Lu, J., Liu, B.F., Zeng, S., & Luo, Q. (2007).
Detection of MMP activity in living cells by a genetically encoded surface-displayed FRET sensor. Biochimica et biophysica acta, 1773(3), 400-7. [PubMed:17187878] [WorldCat] [DOI] - ↑
Ouyang, M., Lu, S., Li, X.Y., Xu, J., Seong, J., Giepmans, B.N., ..., & Wang, Y. (2008).
Visualization of polarized membrane type 1 matrix metalloproteinase activity in live cells by fluorescence resonance energy transfer imaging. The Journal of biological chemistry, 283(25), 17740-8. [PubMed:18441011] [PMC] [WorldCat] [DOI] - ↑
Mitra, R.D., Silva, C.M., & Youvan, D.C. (1996).
Fluorescence resonance energy transfer between blue-emitting and red-shifted excitation derivatives of the green fluorescent protein. Gene, 173(1 Spec No), 13-7. [PubMed:8707050] [WorldCat] [DOI] - ↑
Vanderklish, P.W., Krushel, L.A., Holst, B.H., Gally, J.A., Crossin, K.L., & Edelman, G.M. (2000).
Marking synaptic activity in dendritic spines with a calpain substrate exhibiting fluorescence resonance energy transfer. Proceedings of the National Academy of Sciences of the United States of America, 97(5), 2253-8. [PubMed:10688895] [PMC] [WorldCat] [DOI] - ↑
Uemura, K., Lill, C.M., Li, X., Peters, J.A., Ivanov, A., Fan, Z., ..., & Berezovska, O. (2009).
Allosteric modulation of PS1/gamma-secretase conformation correlates with amyloid beta(42/40) ratio. PloS one, 4(11), e7893. [PubMed:19924286] [PMC] [WorldCat] [DOI] - ↑
Meng, F., Suchyna, T.M., & Sachs, F. (2008).
A fluorescence energy transfer-based mechanical stress sensor for specific proteins in situ. The FEBS journal, 275(12), 3072-87. [PubMed:18479457] [PMC] [WorldCat] [DOI] - ↑
Sakai, R., Repunte-Canonigo, V., Raj, C.D., & Knöpfel, T. (2001).
Design and characterization of a DNA-encoded, voltage-sensitive fluorescent protein. The European journal of neuroscience, 13(12), 2314-8. [PubMed:11454036] [WorldCat] [DOI] - ↑
Tsutsui, H., Karasawa, S., Okamura, Y., & Miyawaki, A. (2008).
Improving membrane voltage measurements using FRET with new fluorescent proteins. Nature methods, 5(8), 683-5. [PubMed:18622396] [WorldCat] [DOI] - ↑
Jin, L., Han, Z., Platisa, J., Wooltorton, J.R., Cohen, L.B., & Pieribone, V.A. (2012).
Single action potentials and subthreshold electrical events imaged in neurons with a fluorescent protein voltage probe. Neuron, 75(5), 779-85. [PubMed:22958819] [PMC] [WorldCat] [DOI] - ↑
Suzuki, Y., Yasunaga, T., Ohkura, R., Wakabayashi, T., & Sutoh, K. (1998).
Swing of the lever arm of a myosin motor at the isomerization and phosphate-release steps. Nature, 396(6709), 380-3. [PubMed:9845076] [WorldCat] [DOI] - ↑
Zeng, W., Seward, H.E., Málnási-Csizmadia, A., Wakelin, S., Woolley, R.J., Cheema, G.S., ..., & Bagshaw, C.R. (2006).
Resonance energy transfer between green fluorescent protein variants: complexities revealed with myosin fusion proteins. Biochemistry, 45(35), 10482-91. [PubMed:16939200] [WorldCat] [DOI] - ↑
Endoh, T., Funabashi, H., Mie, M., & Kobatake, E. (2005).
Method for detection of specific nucleic acids by recombinant protein with fluorescent resonance energy transfer. Analytical chemistry, 77(14), 4308-14. [PubMed:16013840] [WorldCat] [DOI] - ↑
Yano, T., Oku, M., Akeyama, N., Itoyama, A., Yurimoto, H., Kuge, S., ..., & Sakai, Y. (2010).
A novel fluorescent sensor protein for visualization of redox states in the cytoplasm and in peroxisomes. Molecular and cellular biology, 30(15), 3758-66. [PubMed:20498274] [PMC] [WorldCat] [DOI] - ↑
Kolossov, V.L., Spring, B.Q., Clegg, R.M., Henry, J.J., Sokolowski, A., Kenis, P.J., & Gaskins, H.R. (2011).
Development of a high-dynamic range, GFP-based FRET probe sensitive to oxidative microenvironments. Experimental biology and medicine (Maywood, N.J.), 236(6), 681-91. [PubMed:21606117] [PMC] [WorldCat] [DOI]
| Classification | Target | Year | Probe design | References |
| Small molecule | カルシウム | 1997 | 3-2 | [1] |
| Small molecule | サイクリックGMP (cGMP) | 2000, 2001, 2006 | 3-1 | [2][3][4] |
| Small molecule | サイクリックAMP (cAMP) | 2000,2004 | 2, 3-1 | [5][6] |
| Small molecule | イノシトール3リン酸 (IP3) | 2004, 2005, 2006 | 3-1 | [7][8][9] |
| Small molecule | 一酸化窒素 (NO) | 2005, 2006 | 3-1 | [10][11] |
| Small molecule | アデノシン3リン酸 (ATP) | 2012 | 3-1 | [12] |
| Small molecule | エストロゲン | 2004 | 3-3 | [13] |
| Small molecule | アンドロゲン | 2006 | 3-3 | [14] |
| Small molecule | グルココルチコイド受容体リガンド | 2007 | 3-3 | [15] |
| Small molecule | 神経成長因子 | 2008 | 3-3 | [16] |
| Small molecule | 核内受容体 | 2007 | 3-2 | [17] |
| Small molecule | O-N-アセチルグルコサミン (O-GlcNAc) | 2006 | 3-3 | [18] |
| Small molecule | ビタミンA (レチノイン酸) | 2013 | 3-1 | [19] |
| Small molecule | モリブデン酸 | 2013 | 3-1 | [20] |
| Small molecule | グルタミン酸 | 2005 | 3-1 | [21] |
| Small molecule | Zn2+ | 2009 | 2 | [22] |
| Small molecule | Cl- | 2000 | other | [23] |
| Small molecule | 水素イオン濃度 (pH) | 2001 | other | [24] |
| Small molecule | グルコース | 2003 | 3-1 | [25] |
| Small molecule | Maltose | 2002 | 3-1 | [26] |
| Small molecule | Ribose | 2003 | 3-1 | [27] |
| Kinase | Calcium/Calmodulin-dependent protein kinase II (CaMKII) | 2005, 2009, 2011, 2013 | 3-1 | [28][29][30][31] |
| Kinase | Src | 2005, 2005, 2007 | 3-3 | [32][33][34] |
| Kinase | Protein kinase C (PKC) | 2003, 2005 | 3-3, 3-1 | [35][36] |
| Kinase | Protein kinase D (PKD) | 2007 | 3-3 | [37] |
| Kinase | Protein kinase A (PKA) | 2000, 2001 | 3-3 | [38] |
| Kinase | Abl | 2001 | 3-3 | [39] |
| Kinase | Bcr-Abl | 2010 | 3-3 | [40] |
| Kinase | c-Raf | 2005 | 3-1 | [41] |
| Kinase | PAK1 | 2009 | 3-1 | [42] |
| Kinase | B-raf | 2006 | 3-1 | [43] |
| Kinase | ZAP-70 | 2008 | 3-3 | [44] |
| Kinase | Akt | 2003, 2005, 2007 | 3-3 | [45][46][47] |
| Kinase | ERK | 2006, 2007, 2008 | 3-1,3-3,3-3 | [48][49][50] |
| Kinase | Insulin receptor | 2002 | 3-3 | [51] |
| Kinase | Epidermal Growth factor receptor (EGFR) | 2001 | 3-3 | [52] |
| Kinase | Ataxia telangiectasia mutated (ATM) | 2007 | 3-3 | [53] |
| Kinase | Aurora B kinase | 2008 | 3-3 | [54] |
| Kinase | Cyclin B1-CDK1 | 2010 | 3-3 | [55] |
| Kinase | Myosine light chain kinase | 2002 | 3-1 | [56] |
| Kinase | JNK | 2010, 2011 | 3-3 | [57][58] |
| Kinase | RSK | 2011 | 3-3 | [59] |
| Kinase | S6K | 2011 | 3-3 | [60] |
| Kinase | Focal Adhesion Kinase (FAK) | 2008, 2009 | 2, 3-1 | [61][62] |
| Kinase | PLK1 | 2008 | 3-3 | [63] |
| Kinase | SAP3K | 2009 | 3-3 | [64] |
| Kinase | DAPK1 | 2011 | 3-1 | [65] |
| Phosphatase | Calcineurin | 2008, 2013 | 3-1 | [66][67] |
| Small GTPase | Ras | 2001, 2006 | 3-2,2 | [68][69] |
| Small GTPase | Rap | 2001 | 3-2 | [70] |
| Small GTPase | Rac | 2004 | 3-2 | [71] |
| Small GTPase | Rab5 | 2008 | 3-2 | [72] |
| Small GTPase | Rho | 2003, 2011 | 3-2, 2 | [73][74] |
| Small GTPase | Cdc42 | 2004, 2011 | 3-2, 2 | [75][76] |
| Small GTPase | Ral | 2004 | 3-3 | [77] |
| Small GTPase | TC10 | 2006 | 3-2 | [78] |
| Signal transduction | RCC1(GEF of Ran) | 2008 | 3-1 | [79] |
| Signal transduction | CrkII phosphorylation | 2001 | 3-1 | [80] |
| Signal transduction | N-WASP | 2004 | 3-1 | [81][82] |
| Signal transduction | Adrenergic receptor | 2003 | 3-1 | [83] |
| Signal transduction | Parathyroid hormone receptor | 2003 | 3-1 | [84] |
| Signal transduction | Plasma membrane Calcium pump | 2007 | 3-1 | [85] |
| Acetylation | Histone acetylation | 2004, 2009 | 3-3 | [86][87] |
| Lipid | Phosphatidylinositol (3,4,5)-trisphosphate (PIP3) | 2003 | 3-4 | [88] |
| Lipid | Phosphatidylinositol (4,5)-bisphosphate (PIP2) | 2008 | 3-4 | [89] |
| Lipid | Phosphatidylinositol (3,4)-bisphosphate (PI(3,4)P2) | 2008 | 3-4 | [90] |
| Lipid | Phosphatidylinositol 4-phosphate (PI4P) | 2008 | 3-4 | [91] |
| Lipid | Phosphatidic acid | 2010 | 3-4 | [92] |
| Lipid | Diacylglycerol (DAG) | 2006, 2008 | 3-4 | [93][94] |
| Protein interaction | Actin | 2004, 2008 | 2 | [95][96] |
| Protein interaction | PDK1-Akt interaction | 2007 | 2 | [97] |
| Protein interaction | Protein tyrosine phosphatase 1B-receptor tyrosine kinases (PTP 1B-RTKs) interaction | 2002 | 2 | [98] |
| Protein interaction | Breast cancer resistance protein/ATP-binding cassette sub-family G member) BCRP/ABCG | 2010 | 2 | [99] |
| Protein interaction | Cofiin-actin interaction | 2008 | 2 | [100] |
| Protein interaction | PTEN-Myosin V interaction | 2009 | 2 | [101] |
| Protease | Caspase-3 | 1998 | 1 | [102] |
| Protease | Caspase-8 | 2002 | 1 | [103] |
| Protease | Caspase-9 | 2011 | 1 | [104] |
| Protease | Caspase-7 | 2006 | 1 | [105] |
| Protease | Matrix Metalloproteinase (MMP) | 2007, 2008 | 1 | [106][107] |
| Protease | Protease activity (Factor Xa) | 1996 | 1 | [108] |
| Protease | Calpain activity | 2000 | 1 | [109] |
| Protease | Presenilin | 2009 | 3-1 | [110] |
| Other | Strain sensor | 2008 | 3-1 | [111] |
| Other | Membrane potential | 2001, 2008, 2012 | 3-1 | [112][113][114] |
| Other | Myosin II | 1998, 2006 | 3-1 | [115][116] |
| Other | HIV Rev protein | 2005 | 3-1 | [117] |
| Other | Redox | 2010, 2011 | 3-1 | [118][119] |