Category:Adenosine triphosphatases

Subcategories

This category has the following 4 subcategories, out of 4 total.

Media in category "Adenosine triphosphatases"

The following 79 files are in this category, out of 79 total.

• 
  Adenylyl.jpg 355 × 433; 36 KB
  
• An-Essential-Role-for-Katanin-p80-and-Microtubule-Severing-in-Male-Gamete-Production-pgen.1002698.s006.ogv 6.5 s, 1,024 × 1,024; 3.56 MB
  
• An-Essential-Role-for-Katanin-p80-and-Microtubule-Severing-in-Male-Gamete-Production-pgen.1002698.s007.ogv 4.5 s, 1,024 × 1,024; 1.52 MB
  
• An-Essential-Role-for-Katanin-p80-and-Microtubule-Severing-in-Male-Gamete-Production-pgen.1002698.s008.ogv 5.0 s, 1,024 × 1,024; 106 KB
  
• An-Essential-Role-for-Katanin-p80-and-Microtubule-Severing-in-Male-Gamete-Production-pgen.1002698.s009.ogv 5.0 s, 1,024 × 1,024; 54 KB
  
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  Atp i la rotenona.jpg 680 × 324; 91 KB
  
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  ATPase cycle.png 612 × 526; 113 KB
  
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  BiP’s Structure and ATPase Cycle.png 679 × 545; 116 KB
  
• Clamp-loader-ATPases-and-the-evolution-of-DNA-replication-machinery-1741-7007-10-34-S1.ogv 23 s, 640 × 480; 6.22 MB
  
• Clamp-loader-ATPases-and-the-evolution-of-DNA-replication-machinery-1741-7007-10-34-S2.ogv 23 s, 640 × 480; 9.1 MB
  
• Clamp-loader-ATPases-and-the-evolution-of-DNA-replication-machinery-1741-7007-10-34-S3.ogv 5.0 s, 640 × 480; 1.69 MB
  
• Clathrin-Independent-Entry-of-Baculovirus-Triggers-Uptake-of-E.-coli-in-Non-Phagocytic-Human-Cells-pone.0005093.s006.ogv 15 s, 423 × 402; 1.07 MB
  
• Copper-Transport-Protein-Antioxidant-1-Promotes-Inflammatory-Neovascularization-via-Chaperone-and-srep14780-s2.ogv 36 s, 796 × 606; 23.34 MB
  
• Copper-Transport-Protein-Antioxidant-1-Promotes-Inflammatory-Neovascularization-via-Chaperone-and-srep14780-s3.ogv 24 s, 796 × 612; 15.4 MB
  
• Copper-Transport-Protein-Antioxidant-1-Promotes-Inflammatory-Neovascularization-via-Chaperone-and-srep14780-s4.ogv 36 s, 796 × 604; 25.18 MB
  
• Copper-Transport-Protein-Antioxidant-1-Promotes-Inflammatory-Neovascularization-via-Chaperone-and-srep14780-s5.ogv 36 s, 786 × 616; 25.16 MB
  
• Coupling-of-Two-Non-processive-Myosin-5c-Dimers-Enables-Processive-Stepping-along-Actin-Filaments-srep04907-s2.ogv 13 s, 121 × 40; 61 KB
  
• Coupling-of-Two-Non-processive-Myosin-5c-Dimers-Enables-Processive-Stepping-along-Actin-Filaments-srep04907-s3.ogv 40 s, 46 × 124; 544 KB
  
• Coupling-of-Two-Non-processive-Myosin-5c-Dimers-Enables-Processive-Stepping-along-Actin-Filaments-srep04907-s4.ogv 40 s, 63 × 152; 785 KB
  
• Coupling-of-Two-Non-processive-Myosin-5c-Dimers-Enables-Processive-Stepping-along-Actin-Filaments-srep04907-s5.ogv 47 s, 60 × 28; 91 KB
  
• DHC ADP.webm 29 s, 624 × 606; 8.9 MB
  
• Drosophila-Spastin-Regulates-Synaptic-Microtubule-Networks-and-Is-Required-for-Normal-Motor-Function-pbio.0020429.sv001.ogv 1 min 38 s, 384 × 288; 3.78 MB
  
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  Estructura de la P4-ATPasa.png 2,107 × 1,594; 340 KB
  
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  Estructura P4-ATPasa.png 3,700 × 2,081; 380 KB
  
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  Estrutura ATP13A2.jpg 1,055 × 795; 109 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s003.ogv 1.4 s, 300 × 375; 199 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s004.ogv 1.4 s, 300 × 375; 196 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s005.ogv 1.8 s, 300 × 397; 263 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s006.ogv 7.3 s, 1,024 × 1,024; 2.54 MB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s007.ogv 0.0 s, 1,024 × 1,024; 2.17 MB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s008.ogv 0.0 s, 800 × 800; 783 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s009.ogv 1.7 s, 800 × 800; 440 KB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s010.ogv 4.2 s, 1,108 × 1,108; 3.45 MB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s011.ogv 4.2 s, 1,082 × 1,108; 3.55 MB
  
• Flexibility-within-the-Rotor-and-Stators-of-the-Vacuolar-H+-ATPase-pone.0082207.s012.ogv 1.7 s, 1,250 × 1,109; 1.21 MB
  
• 
  Fo subunit of ATPase C1. Picture Created in PyMol.png 657 × 404; 245 KB
  
• Fusion-of-Protein-Aggregates-Facilitates-Asymmetric-Damage-Segregation-pbio.1001886.s005.ogv 8.7 s, 212 × 218; 280 KB
  
• Fusion-of-Protein-Aggregates-Facilitates-Asymmetric-Damage-Segregation-pbio.1001886.s006.ogv 8.7 s, 224 × 242; 239 KB
  
• 
  Gastric hydrogen potassium ATPase mechanism.svg 600 × 400; 2 KB
  
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  Mecanismes tranport atpasa.png 991 × 340; 146 KB
  
• 
  Mecanismes tranport flipasa.png 991 × 340; 146 KB
  
• Molecular-snapshots-of-the-Pex16-AAA+-complex-in-action-ncomms8331-s2.ogv 0.8 s, 833 × 830; 288 KB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv001.ogv 34 s, 320 × 226; 5.13 MB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv002.ogv 20 s, 320 × 226; 319 KB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv003.ogv 34 s, 320 × 192; 3.53 MB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv004.ogv 41 s, 320 × 190; 419 KB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv005.ogv 27 s, 240 × 240; 5.16 MB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv006.ogv 6.8 s, 240 × 240; 157 KB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv007.ogv 33 s, 320 × 90; 2.94 MB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv008.ogv 12 s, 320 × 108; 111 KB
  
• Noise-Induced-Min-Phenotypes-in-E.-coli-pcbi.0020080.sv009.ogv 1.2 s, 320 × 110; 17 KB
  
• Non-SMC-condensin-I-complex-proteins-control-chromosome-segregation-and-survival-of-proliferating-1471-213X-9-40-S3.ogv 7.5 s, 640 × 480; 164 KB
  
• Non-SMC-condensin-I-complex-proteins-control-chromosome-segregation-and-survival-of-proliferating-1471-213X-9-40-S4.ogv 5.1 s, 220 × 256; 256 KB
  
• Non-SMC-condensin-I-complex-proteins-control-chromosome-segregation-and-survival-of-proliferating-1471-213X-9-40-S5.ogv 5.1 s, 220 × 257; 135 KB
  
• Non-SMC-condensin-I-complex-proteins-control-chromosome-segregation-and-survival-of-proliferating-1471-213X-9-40-S6.ogv 7.1 s, 316 × 330; 1.92 MB
  
• Pathways-of-allosteric-regulation-in-Hsp70-chaperones-ncomms9308-s2.ogv 2.7 s, 1,434 × 1,253; 1.41 MB
  
• Pathways-of-allosteric-regulation-in-Hsp70-chaperones-ncomms9308-s3.ogv 2.7 s, 1,533 × 839; 1.31 MB
  
• Pathways-of-allosteric-regulation-in-Hsp70-chaperones-ncomms9308-s4.ogv 16 s, 1,364 × 1,376; 4.01 MB
  
• Pyrazoleamide-compounds-are-potent-antimalarials-that-target-Na+-homeostasis-in-intraerythrocytic-ncomms6521-s2.ogv 34 s, 392 × 352; 741 KB
  
• Pyrazoleamide-compounds-are-potent-antimalarials-that-target-Na+-homeostasis-in-intraerythrocytic-ncomms6521-s3.ogv 23 s, 452 × 452; 1.3 MB
  
• Quantitative-Gait-Analysis-Using-a-Motorized-Treadmill-System-Sensitively-Detects-Motor-pone.0152413.s002.ogv 7.0 s, 658 × 218; 1.57 MB
  
• Quantitative-Gait-Analysis-Using-a-Motorized-Treadmill-System-Sensitively-Detects-Motor-pone.0152413.s004.ogv 9.1 s, 658 × 218; 1.81 MB
  
• Quantitative-Gait-Analysis-Using-a-Motorized-Treadmill-System-Sensitively-Detects-Motor-pone.0152413.s005.ogv 5.6 s, 658 × 218; 1.28 MB
  
• S.-pombe-Kinesins-8-Promote-Both-Nucleation-and-Catastrophe-of-Microtubules-pone.0030738.s011.ogv 6.0 s, 256 × 255; 81 KB
  
• Synergistic-effect-of-ATP-for-RuvA–RuvB–Holliday-junction-DNA-complex-formation-srep18177-s1.ogv 20 s, 128 × 128; 5.49 MB
  
• The-Hexameric-Structures-of-Human-Heat-Shock-Protein-90-pone.0019961.s001.ogv 7.7 s, 600 × 600; 12.69 MB
  
• The-ISWI-Chromatin-Remodeler-Organizes-the-hsrω-ncRNA–Containing-Omega-Speckle-Nuclear-Compartments-pgen.1002096.s016.ogv 46 s, 720 × 480; 4.49 MB
  
• The-ISWI-Chromatin-Remodeler-Organizes-the-hsrω-ncRNA–Containing-Omega-Speckle-Nuclear-Compartments-pgen.1002096.s017.ogv 33 s, 1,024 × 768; 2.34 MB
  
• The-MinCDJ-System-in-Bacillus-subtilis-Prevents-Minicell-Formation-by-Promoting-Divisome-Disassembly-pone.0009850.s009.ogv 0.0 s, 816 × 832; 394 KB
  
• The-MinCDJ-System-in-Bacillus-subtilis-Prevents-Minicell-Formation-by-Promoting-Divisome-Disassembly-pone.0009850.s010.ogv 0.0 s, 816 × 896; 6.82 MB
  
• TRIM32-Cytoplasmic-Body-Formation-Is-an-ATP-Consuming-Process-Stimulated-by-HSP70-in-Cells-pone.0169436.s006.ogv 18 s, 528 × 528; 132 KB
  
• TRIM32-Cytoplasmic-Body-Formation-Is-an-ATP-Consuming-Process-Stimulated-by-HSP70-in-Cells-pone.0169436.s007.ogv 18 s, 528 × 528; 240 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s2.ogv 3.3 s, 320 × 160; 20 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s3.ogv 4.9 s, 320 × 180; 35 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s4.ogv 3.1 s, 320 × 180; 18 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s5.ogv 5.7 s, 360 × 180; 39 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s6.ogv 4.4 s, 320 × 180; 23 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s7.ogv 3.0 s, 320 × 180; 14 KB
  
• TumRacGAP-functions-as-a-switch-activating-the-Pavkinesin-6-motor-ncomms11182-s8.ogv 4.3 s, 320 × 180; 18 KB