Results 181 to 190 of about 315,665 (286)

Mitochondrial protein import [PDF]

, 1989
Ades, Ades, Adrian, Ainger, Allison, Alt, Aquila, Aquila, Arakawa, Arends, Argan, Argan, Baker, Banroques, Basile, Beckmann, Bedwell, Behra, Bellion, Beltzer, Beltzer, Berkhout, Bhasker, Bhat, Blobel, Borst, Bouillaud, Boutry, Brandriss, Braun, Burns, Böhni, Böhni, Cerletti, Chatton, Chen, Chen, Chen, Chen, Chen, Cheng, Chien, Chien, Chirico, Chu, Conboy, Conboy, Coruzzi, Craig, Dahl, Daum, Daum, De Haan, De Jong, De Lange, De Lange, Deshaies, Dickerson, Dieckmann, Dieckmann, Douglas, Duffaud, Dumont, Eilers, Eilers, Eilers, Ellis, Ellis, Emr, Epand, Evans, Farrell, Farrell, Faye, Firgaira, Fisher, Flügge, Foury, Fox, Freeman, Freitag, Fujiki, Fujiki, Gabellini, Gabellini, Gasser, Gasser, Gasser, Gay, Gearing, Geller, Gillespie, Gilmore, Gilmore, Grant, Grossmann, Guiard, Hackenbrock, Hallemayer, Hallermayer, Hallewell, Hampsey, Hansen, Harmey, Harmey, Harmey, Harmey, Harnisch, Hartl, Hartl, Hartl, Hartl, Hase, Hase, Hase, Hatalova, Hauska, Hawlitschek, Hay, Heinrich, Hemmingsen, Hennig, Hennig, Hennig, Henning, Hensgen, Ho, Ho, Horwich, Horwich, Horwich, Horwich, Horwich, Horwich, Hunter, Hurt, Hurt, Hurt, Hurt, Hurt, Hurt, Hurt, Hurt, Imanaka, Ito, Jaussi, Jaussi, Joh, Just, Kanazawa, Kaput, Kellems, Kellems, Kellens, Keng, Kirwin, Kleene, Koerner, Koerner, Koike, Kolansky, Kolarov, Korb, Kraus, Kraus, Kraus, Kraus, Krebs, Kruse, Kryzwicki, Kun, Labouesse, Lazarow, Lederer, Lennart-Nilsson, Lewin, Lewin, Lindquist, Lingelbach, Lomax, Lubben, Lustig, Lustig, Maarse, Maarse, Maccecchini, Maccecchini, Macino, Maher, Marres, Marzuki, Matsubara, Matsuura, McAda, McGraw, McIntyre, Meyer, Meyer, Meyer, Michel, Mihara, Mihara, Mihara, Mihara, Miura, Miura, Mori, Mori, Morita, Morohashi, Morohashi, Morohashi, Mueckler, Mueckler, Mueckler, Myers, Myers, Müller, Müller, Nagata, Nakagawa, Nargang, Natsoulis, Nelson, Nelson, Ness, Neupert, Neupert, Nguyen, Nguyen, Nguyen, Nguyen, Nicholson, Nicholson, Nicholson, Nicholson, Nishikimi, Nyunoya, Oda, Oda, Ohashi, Ohba, Ohba, Ohta, Ohta, Okamura, Okamura, Ono, Ono, Ono, Ono, Ou, Ou, Oudshoorn, Pain, Pain, Pape, Pape, Park, Patterson, Pelham, Perara, Pfaller, Pfaller, Pfaller, Pfaller, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pfanner, Pillar, Pollock, Pratje, Pratje, Randall, Randall, Raymond, Reid, Reid, Richter, Ricquier, Ridley, Rietveld, Riezman, Riezman, Riezman, Robinson, Roise, Roise, Rothblatt, Rothman, Runswick, Rödel, Römisch, Sabatini, Sachs, Sadler, Saraste, Schatz, Schlenstedt, Schleyer, Schleyer, Schleyer, Schmeizer, Schmidt, Schmidt, Schmidt, Schmidt, Schmidt, Schneller, Schwaiger, Schägger, Sebald, Shore, Sidhu, Sierra, Simmaco, Skerjank, Smagula, Stellwagen, Stuart, Suissa, Suissa, Surguchov, Suske, Sztul, Söllner, Takeda, Takeda, Takiguchi, Tamm, Taniuchi, Teintze, Tropschug, Tzagoloff, Tzagoloff, Ueda, Urban-Grimal, Van Loon, Van Loon, Van Loon, Van Loon, Van Loon, Van Loon, Van Loon, Van Loon, Van Steeg, Vasarotti, Vasarotti, Veloso, Velours, Verner, Vestweber, Viebrock, Von Heijne, Walter, Walter, Walter, Watanabe, Waters, Watts, Weiss, Werner, Wickner, Wiech, Wielburski, Wierenga, Witte, Wold, Woodrow, Wright, Wright, Wu, Yaffe, Yaffe, Yamane, Yoshida, Yoshida, Young, Zimmermann, Zimmermann, Zimmermann, Zimmermann, Zimmermann, Zimmermann, Zwizinski, Zwizinski, Zwizinski, Zwizinski   +395 more
core   +1 more source

Resonant Domain Wall Dynamics in a Three‐Dimensional Magnetic Nano Double Helix

Advanced Materials, EarlyView.
3D magnetic nanostructures promise exciting possibilities for magnetization dynamics. However, experimental realizations remain scarce. In nanoprinted cobalt double helices, time‐resolved X‐ray microscopy reveals harmonic domain wall dynamics. Simulations identify the mode and additional higher‐frequency resonances, revealing a rich dynamic landscape ...
Pamela Morales‐Fernández, Iason Konstantinos‐Douveas, Claas Abert, Elina Zhakina, Sandra Ruiz‐Gómez, Claudia Fernández‐González, Luke Alexander Turnbull, Sebastian Wintz, Markus König, Simone Finizio, Markus Weigand, Naëmi Leo, Dieter Suess, Aurelio Hierro‐Rodríguez, Amalio Fernández‐Pacheco, Claire Donnelly   +15 more
wiley   +1 more source

Synthesis and intracellular transport of mitochondrial proteins [PDF]

, 1985
A Lustig, A Lustig, A Ohashi, A Viebrock, AJ Lamb, AP Autor, AS Lewin, AS Lewin, B Hennig, B Schmidt, BE Roberts, BG Barrell, C Cote, C Zwizinski, CJ Leaver, DI Meyer, DI Meyer, DL Stigall, DM Kolansky, E Komar, E Marra, E Pratje, E Schmelzer, G Attardi, G Blobel, G Daum, G Daum, G Hallermayer, G Hallermayer, G Kreibich, G Kreil, G Macino, G Reid, G Schatz, G Schatz, G Schatz, G Srivastava, GC Shore, GC Shore, H Freitag, H Koehler, H Korb, H Riezman, H Weiss, IG Macreadie, IZ Ades, IZ Ades, J Kaput, JG Conboy, JP Kraus, K Mihara, K Mihara, K Mihara, K Watanabe, L Ernster, L Randall, LA Grivell, LE Aziz, M Inouye, M Klingenberg, M Klingenberg, M Maccechini, M Mori, M Mori, M Schleyer, M Suissa, M Teintze, M Wikstrom, M Yamamoto, M-L Maccechini, MA Harmey, MA Harmey, MD Hampsey, MM Mueckler, N Cerletti, N Nabi, N Nelson, NK Bhat, P Boehni, P Boehni, P Boogart van den, P Borst, P Borst, P Borst, P McAda, P Sonderegger, P Walter, PC Heinrich, PC Kreibich, PG Adolphus, R Jaussi, R Michel, R Sakakibara, R Zimmermann, R Zimmermann, R Zimmermann, R Zimmermann, RE Kellems, RE Kellems, RO Poyton, S Matsuura, S Miura, S Passarella, S Werner, SD Emr, SM Gasser, SM Gasser, SM Gasser, T Hunt, T Monta, T Oda, VA Rucker, W Neupert, W Wickner, Y Kamisaki, Y Raymond, Y Sagara, Y Yoshida   +117 more
core   +1 more source

Electrolyte‐Induced Interfacial/Bulk Dual Regulation Enables Negligible Capacity Decay in Li‐Rich Cathodes

Advanced Materials, EarlyView.
This work report a n electrolyte‑induced interfacial/bulk dual regulation strategy that enables negligible capacity decay in li‑rich cathodes. ABSTRACT Lithium‐rich manganese‐based oxides (LRMO) suffer from rapid capacity decay, mainly driven by interfacial instability and bulk structural degradation associated with Jahn‐Teller (J‐T) distortion in Mn3+‐
Tianqi Yang, Min Jiang, Jiatao Lou, Zhouyu Huang, Xingjun Li, Liuqi Wang, Qingru Zhou, Lun Li, Liuyi Hu, Wei Liu, Yuzhi He, Xingyu Wang, Zhengbo Liu, Wenkui Zhang, Jun Zhang, Xinhui Xia, Yang Ren, Qi Liu   +17 more
wiley   +1 more source

LEM-Domain-Containing Inner Nuclear Membrane Proteins: Emerging Regulators of Intranuclear Signaling. [PDF]

Int J Mol Sci
Lee B, Lee H, Shim J.
europepmc   +1 more source

Correction to 'Structural insights into chromosome attachment to the nuclear envelope by an inner nuclear membrane protein Bqt4 in fission yeast'. [PDF]

Nucleic Acids Res, 2021
Hu C, Inoue H, Sun W, Takeshita Y, Huang Y, Xu Y, Kanoh J, Chen Y.   +7 more
europepmc   +1 more source

Plasmonic Nanomachines: Creating Local Potential Gradients and Motions

Advanced Materials, EarlyView.
Plasmonic nanomachines can generate optical, thermal, and chemical potential gradients to drive directional rectilinear, rotational, and twisting motions at the nanometer scale. The integration of multimodal plasmonic forces with functional materials and programmed structural distortions enables precise spatiotemporal actuation, thereby providing a ...
Yoonhee Kim, Soohyun Ji, Donghyun Choi, Jwa‐Min Nam   +3 more
wiley   +1 more source

A-type lamins anchor emerin at the inner nuclear membrane via two independent binding sites. [PDF]

J Biol Chem
Odell J, Nedza K, Lammerding J.
europepmc   +1 more source

Infection-induced chromatin modifications facilitate translocation of herpes simplex virus capsids to the inner nuclear membrane. [PDF]

PLoS Pathog, 2021
Aho V, Salminen S, Mattola S, Gupta A, Flomm F, Sodeik B, Bosse JB, Vihinen-Ranta M.   +7 more
europepmc   +1 more source

Integrating ZnO/Ag2O@g‐C3N4‐Based Nanocomposites Into a Carrageenan Matrix to Efficiently Remove Heavy Metals From Water

Advanced Materials Interfaces, EarlyView.
ABSTRACT This research focused on characterizing graphitic carbon nitride (g‐C3N4) nanocomposites incorporated with ZnO and Ag2O nanoparticles, and carrageenan to remove heavy metals. The ZnO/Ag2O@ g‐C3N4 and ZnO/Ag2O/g‐C3N4@Carr nanocomposites demonstrated thermal stability of 97.40% (108.81°C) and 82.80% (188.99°C) for TGA.
Feziwe B. Mamba, Bhekani S. Mbuli, James Ramontja   +2 more
wiley   +1 more source