Category:Molecular models

Media in category "Molecular models"

The following 200 files are in this category, out of 285 total.

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  1-Undecanol molecular model.jpg 4,080 × 3,060; 6.23 MB
  
• 3D-Multi-Cell-Simulation-of-Tumor-Growth-and-Angiogenesis-pone.0007190.s002.ogv 40 s, 300 × 300; 8.51 MB
  
• 3D-Multi-Cell-Simulation-of-Tumor-Growth-and-Angiogenesis-pone.0007190.s003.ogv 40 s, 270 × 270; 7.73 MB
  
• A-Common-Model-for-Cytokine-Receptor-Activation-Combined-Scissor-Like-Rotation-and-Self-Rotation-of-pcbi.1002427.s009.ogv 13 s, 800 × 600; 364 KB
  
• A-Helical-Structural-Nucleus-Is-the-Primary-Elongating-Unit-of-Insulin-Amyloid-Fibrils-pbio.0050134.sv001.ogv 1 min 0 s, 320 × 240; 2.68 MB
  
• A-Helical-Structural-Nucleus-Is-the-Primary-Elongating-Unit-of-Insulin-Amyloid-Fibrils-pbio.0050134.sv002.ogv 0.0 s, 240 × 240; 3.1 MB
  
• A-Novel-Mechanism-for-Small-Heat-Shock-Proteins-to-Function-as-Molecular-Chaperones-srep08811-s2.ogv 1 min 5 s, 320 × 240; 2.93 MB
  
• A-previously-unobserved-conformation-for-the-human-Pex5p-receptor-suggests-roles-for-intrinsic-1472-6807-7-24-S2.ogv 10 s, 640 × 480; 3.95 MB
  
• A-Structural-and-Mutagenic-Blueprint-for-Molecular-Recognition-of-Strychnine-and-d-Tubocurarine-by-pbio.1001034.s004.ogv 20 s, 848 × 480; 1.5 MB
  
• 
  Adsorption of Nitrogen onto the Surface of Carbon.png 1,317 × 712; 2.69 MB
  
• Allosteric-Communication-in-Myosin-V-From-Small-Conformational-Changes-to-Large-Directed-Movements-pcbi.1000129.s001.ogv 6.4 s, 1,052 × 928; 1.85 MB
  
• Allosteric-Communication-in-Myosin-V-From-Small-Conformational-Changes-to-Large-Directed-Movements-pcbi.1000129.s002.ogv 5.1 s, 1,060 × 624; 1,023 KB
  
• An-Integrated-Framework-Advancing-Membrane-Protein-Modeling-and-Design-pcbi.1004398.s008.ogv 21 s, 1,068 × 600; 14.28 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s012.ogv 17 s, 504 × 478; 8.43 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s013.ogv 17 s, 504 × 478; 8.52 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s015.ogv 17 s, 504 × 478; 8.66 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s020.ogv 17 s, 503 × 323; 1.08 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s022.ogv 17 s, 504 × 478; 7.94 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s023.ogv 17 s, 504 × 478; 8.04 MB
  
• Are-Coiled-Coils-of-Dimeric-Kinesins-Unwound-during-Their-Walking-on-Microtubule?-pone.0036071.s024.ogv 17 s, 504 × 478; 8.22 MB
  
• Artificial-targeting-of-misfolded-cytosolic-proteins-to-endoplasmic-reticulum-as-a-mechanism-for-srep12088-s2.ogv 5.8 s, 1,024 × 1,024; 3.56 MB
  
• Artificial-targeting-of-misfolded-cytosolic-proteins-to-endoplasmic-reticulum-as-a-mechanism-for-srep12088-s3.ogv 8.1 s, 1,024 × 1,024; 1.59 MB
  
• Artificial-targeting-of-misfolded-cytosolic-proteins-to-endoplasmic-reticulum-as-a-mechanism-for-srep12088-s4.ogv 9.6 s, 1,024 × 1,024; 1.14 MB
  
• Asymmetric-ring-structure-of-Vps4-required-for-ESCRT-III-disassembly-ncomms9781-s2.ogv 16 s, 1,920 × 1,018; 3.15 MB
  
• Asymmetric-ring-structure-of-Vps4-required-for-ESCRT-III-disassembly-ncomms9781-s3.ogv 35 s, 1,280 × 1,024; 49.03 MB
  
• Atomic-description-of-the-immune-complex-involved-in-heparin-induced-thrombocytopenia-ncomms9277-s2.ogv 5.0 s, 524 × 729; 1.53 MB
  
• Atomic-description-of-the-immune-complex-involved-in-heparin-induced-thrombocytopenia-ncomms9277-s3.ogv 5.0 s, 650 × 616; 2.12 MB
  
• Atomic-view-of-the-histidine-environment-stabilizing-higher-pH-conformations-of-pH-dependent-ncomms8771-s2.ogv 3.2 s, 640 × 480; 643 KB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s005.ogv 17 s, 768 × 576; 3.57 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s006.ogv 19 s, 768 × 576; 5.02 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s007.ogv 19 s, 768 × 576; 7.29 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s008.ogv 19 s, 768 × 576; 7.07 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s009.ogv 27 s, 768 × 576; 10.86 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s010.ogv 9.6 s, 768 × 576; 3.7 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s011.ogv 9.6 s, 768 × 576; 3.59 MB
  
• Changes-in-Dynamics-upon-Oligomerization-Regulate-Substrate-Binding-and-Allostery-in-Amino-Acid-pcbi.1002201.s012.ogv 19 s, 768 × 576; 6.31 MB
  
• Chromophore-Protonation-State-Controls-Photoswitching-of-the-Fluoroprotein-asFP595-pcbi.1000034.s001.ogv 27 s, 416 × 320; 6.08 MB
  
• Chromophore-Protonation-State-Controls-Photoswitching-of-the-Fluoroprotein-asFP595-pcbi.1000034.s018.ogv 13 s, 416 × 320; 2.91 MB
  
• 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
  
• Complexes-of-Neutralizing-and-Non-Neutralizing-Affinity-Matured-Fabs-with-a-Mimetic-of-the-Internal-pone.0078187.s002.ogv 14 s, 600 × 600; 4.66 MB
  
• Conformational-Reorganization-of-the-SARS-Coronavirus-Spike-Following-Receptor-Binding-Implications-pone.0001082.s001.ogv 22 s, 350 × 348; 3.88 MB
  
• Conformational-Reorganization-of-the-SARS-Coronavirus-Spike-Following-Receptor-Binding-Implications-pone.0001082.s002.ogv 4.0 s, 1,024 × 768; 1.02 MB
  
• Conformational-Sampling-and-Nucleotide-Dependent-Transitions-of-the-GroEL-Subunit-Probed-by-pcbi.1002004.s005.ogv 1 min 40 s, 480 × 480; 3.8 MB
  
• Control-of-cytoplasmic-dynein-force-production-and-processivity-by-its-C-terminal-domain-ncomms7206-s2.ogv 7.1 s, 153 × 134; 72 KB
  
• Control-of-cytoplasmic-dynein-force-production-and-processivity-by-its-C-terminal-domain-ncomms7206-s3.ogv 13 s, 156 × 155; 164 KB
  
• Control-of-cytoplasmic-dynein-force-production-and-processivity-by-its-C-terminal-domain-ncomms7206-s4.ogv 14 s, 97 × 99; 99 KB
  
• Coordinated-Movement-of-Cytoplasmic-and-Transmembrane-Domains-of-RyR1-upon-Gating-pbio.1000085.sv001.ogv 1 min 7 s, 300 × 300; 4.18 MB
  
• Coordinated-Movement-of-Cytoplasmic-and-Transmembrane-Domains-of-RyR1-upon-Gating-pbio.1000085.sv002.ogv 1 min 9 s, 300 × 300; 5.54 MB
  
• Correct-folding-of-an-α-helix-and-a-β-hairpin-using-a-polarized-2D-torsional-potential-srep10359-s2.ogv 12 min 0 s, 384 × 288; 17.92 MB
  
• Corresponding-Functional-Dynamics-across-the-Hsp90-Chaperone-Family-Insights-from-a-Multiscale-pcbi.1002433.s017.ogv 0.0 s, 688 × 512; 12.22 MB
  
• Corresponding-Functional-Dynamics-across-the-Hsp90-Chaperone-Family-Insights-from-a-Multiscale-pcbi.1002433.s018.ogv 0.0 s, 688 × 512; 15.84 MB
  
• Corresponding-Functional-Dynamics-across-the-Hsp90-Chaperone-Family-Insights-from-a-Multiscale-pcbi.1002433.s019.ogv 15 s, 512 × 512; 7.7 MB
  
• Cortical-Factor-Feedback-Model-for-Cellular-Locomotion-and-Cytofission-pcbi.1000310.s001.ogv 40 s, 768 × 576; 2.12 MB
  
• Cortical-Factor-Feedback-Model-for-Cellular-Locomotion-and-Cytofission-pcbi.1000310.s002.ogv 41 s, 768 × 576; 1.78 MB
  
• Cortical-Factor-Feedback-Model-for-Cellular-Locomotion-and-Cytofission-pcbi.1000310.s003.ogv 7.3 s, 768 × 576; 546 KB
  
• Cortical-Factor-Feedback-Model-for-Cellular-Locomotion-and-Cytofission-pcbi.1000310.s004.ogv 3.4 s, 768 × 576; 466 KB
  
• Cryo-Electron-Tomographic-Structure-of-an-Immunodeficiency-Virus-Envelope-Complex-In-Situ-ppat.0020083.sv001.ogv 17 s, 640 × 480; 418 KB
  
• Cryo-EM-structure-of-lysenin-pore-elucidates-membrane-insertion-by-an-aerolysin-family-protein-ncomms11293-s2.ogv 9.3 s, 1,208 × 1,045; 15.61 MB
  
• Cyclophilin-A-stabilizes-the-HIV-1-capsid-through-a-novel-non-canonical-binding-site-ncomms10714-s3.ogv 30 s, 768 × 752; 16.32 MB
  
• Decrypting-the-Sequence-of-Structural-Events-during-the-Gating-Transition-of-Pentameric-Ligand-pcbi.1001046.s003.ogv 0.0 s, 656 × 672; 4.11 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s2.ogv 36 s, 1,200 × 750; 12.68 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s3.ogv 35 s, 1,200 × 750; 5.77 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s4.ogv 41 s, 1,200 × 750; 17.2 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s5.ogv 45 s, 1,024 × 768; 25.42 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s6.ogv 45 s, 1,024 × 768; 19.12 MB
  
• Deep-and-high-resolution-three-dimensional-tracking-of-single-particles-using-nonlinear-and-ncomms8874-s7.ogv 45 s, 1,024 × 768; 36.76 MB
  
• Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s001.ogv 15 s, 758 × 479; 10.3 MB
  
• Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s002.ogv 15 s, 758 × 479; 10.27 MB
  
• Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s003.ogv 3.2 s, 758 × 479; 1.36 MB
  
• Diffusion-Crowding-&-Protein-Stability-in-a-Dynamic-Molecular-Model-of-the-Bacterial-Cytoplasm-pcbi.1000694.s014.ogv 6.0 s, 330 × 330; 4 KB
  
• Discovering-Conformational-Sub-States-Relevant-to-Protein-Function-pone.0015827.s010.ogv 3.3 s, 640 × 480; 458 KB
  
• Discovering-Conformational-Sub-States-Relevant-to-Protein-Function-pone.0015827.s011.ogv 3.2 s, 640 × 240; 320 KB
  
• Discovering-Conformational-Sub-States-Relevant-to-Protein-Function-pone.0015827.s012.ogv 6.2 s, 640 × 240; 277 KB
  
• Dynamic-Prestress-in-a-Globular-Protein-pcbi.1002509.s009.ogv 0.0 s, 656 × 608; 12.71 MB
  
• Dynamic-Prestress-in-a-Globular-Protein-pcbi.1002509.s010.ogv 0.0 s, 656 × 608; 9.08 MB
  
• Dynamic-Prestress-in-a-Globular-Protein-pcbi.1002509.s011.ogv 0.0 s, 656 × 608; 10.11 MB
  
• Effects-of-site-directed-mutagenesis-of-mglA-on-motility-and-swarming-of-Myxococcus-xanthus-1471-2180-10-295-S2.ogv 6.8 s, 216 × 161; 270 KB
  
• Effects-of-site-directed-mutagenesis-of-mglA-on-motility-and-swarming-of-Myxococcus-xanthus-1471-2180-10-295-S3.ogv 2.5 s, 216 × 161; 167 KB
  
• Effects-of-site-directed-mutagenesis-of-mglA-on-motility-and-swarming-of-Myxococcus-xanthus-1471-2180-10-295-S4.ogv 2.5 s, 216 × 161; 156 KB
  
• Effects-of-site-directed-mutagenesis-of-mglA-on-motility-and-swarming-of-Myxococcus-xanthus-1471-2180-10-295-S5.ogv 2.0 s, 696 × 520; 965 KB
  
• Elasticity-pbio.1001261.s008.ogv 16 s, 1,627 × 629; 1.18 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s003.ogv 27 s, 600 × 600; 5.08 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s004.ogv 27 s, 600 × 600; 5.23 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s005.ogv 26 s, 600 × 600; 5.29 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s006.ogv 27 s, 600 × 600; 5.74 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s007.ogv 26 s, 600 × 600; 5.57 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s008.ogv 9.9 s, 526 × 616; 1.27 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s009.ogv 4.9 s, 400 × 616; 3.13 MB
  
• Electron-Tomography-of-Cryofixed-Isometrically-Contracting-Insect-Flight-Muscle-Reveals-Novel-Actin-pone.0012643.s010.ogv 8.2 s, 386 × 616; 1.86 MB
  
• Electrostatically-Biased-Binding-of-Kinesin-to-Microtubules-pbio.1001207.s005.ogv 55 s, 1,440 × 652; 2.48 MB
  
• Electrostatically-Biased-Binding-of-Kinesin-to-Microtubules-pbio.1001207.s006.ogv 14 s, 450 × 450; 4.24 MB
  
• Electrostatically-Biased-Binding-of-Kinesin-to-Microtubules-pbio.1001207.s007.ogv 32 s, 550 × 550; 7.28 MB
  
• Energetics-and-Structural-Characterization-of-the-large-scale-Functional-Motion-of-Adenylate-Kinase-srep08425-s2.ogv 1 min 47 s, 768 × 576; 14.92 MB
  
• Epitope-Flexibility-and-Dynamic-Footprint-Revealed-by-Molecular-Dynamics-of-a-pMHC-TCR-Complex-pcbi.1002404.s001.ogv 33 s, 1,920 × 1,080; 52.68 MB
  
• Epitope-Flexibility-and-Dynamic-Footprint-Revealed-by-Molecular-Dynamics-of-a-pMHC-TCR-Complex-pcbi.1002404.s002.ogv 33 s, 1,520 × 1,008; 47.36 MB
  
• Evidence-of-a-Double-Lid-Movement-in-Pseudomonas-aeruginosa-Lipase-Insights-from-Molecular-Dynamics-pcbi.0010028.sv001.ogv 1 min 15 s, 320 × 240; 1.68 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s013.ogv 1.4 s, 1,280 × 960; 1.37 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s014.ogv 1.4 s, 1,280 × 960; 1.26 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s015.ogv 1.4 s, 1,280 × 960; 1.27 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s016.ogv 1.4 s, 1,024 × 768; 1.18 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s017.ogv 1.4 s, 1,024 × 768; 1.37 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s018.ogv 1.4 s, 1,024 × 768; 1.23 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s019.ogv 1.4 s, 1,280 × 960; 1.23 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s020.ogv 1.4 s, 1,280 × 960; 1.24 MB
  
• Evolutionarily-Conserved-Linkage-between-Enzyme-Fold-Flexibility-and-Catalysis-pbio.1001193.s021.ogv 1.4 s, 1,280 × 960; 1.25 MB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s008.ogv 6.1 s, 74 × 62; 39 KB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s009.ogv 6.1 s, 72 × 65; 21 KB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s010.ogv 6.1 s, 74 × 63; 17 KB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s011.ogv 6.1 s, 72 × 64; 20 KB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s012.ogv 6.1 s, 72 × 63; 30 KB
  
• Evolutionarily-Divergent-Unstable-Filamentous-Actin-Is-Essential-for-Gliding-Motility-in-ppat.1002280.s013.ogv 6.1 s, 72 × 65; 18 KB
  
• Exploring-the-Universe-of-Protein-Structures-beyond-the-Protein-Data-Bank-pcbi.1000957.s008.ogv 0.0 s, 656 × 832; 6.59 MB
  
• 
  Figure 1 Horizontal and vertical projections of 1,2-dimethylpropyl group.png 1,952 × 2,310; 424 KB
  
• Fluorescent-Peptide-Biosensor-for-Probing-the-Relative-Abundance-of-Cyclin-Dependent-Kinases-in-pone.0026555.s005.ogv 3.0 s, 198 × 150; 113 KB
  
• 
  Fragment of Sus scrofa microtubule stabilized with taxol and peloruside.jpg 9,171 × 9,196; 8.24 MB
  
• From-light-harvesting-to-photoprotection-structural-basis-of-the-dynamic-switch-of-the-major-srep15661-s2.ogv 45 s, 854 × 480; 46.67 MB
  
• From-light-harvesting-to-photoprotection-structural-basis-of-the-dynamic-switch-of-the-major-srep15661-s3.ogv 18 s, 352 × 288; 7.55 MB
  
• From-light-harvesting-to-photoprotection-structural-basis-of-the-dynamic-switch-of-the-major-srep15661-s4.ogv 31 s, 304 × 288; 8.84 MB
  
• From-light-harvesting-to-photoprotection-structural-basis-of-the-dynamic-switch-of-the-major-srep15661-s5.ogv 30 s, 304 × 288; 8.54 MB
  
• GFPs-Mechanical-Intermediate-States-pone.0046962.s003.ogv 1 min 9 s, 852 × 480; 23.95 MB
  
• HAMLET-Binding-to-α-Actinin-Facilitates-Tumor-Cell-Detachment-pone.0017179.s009.ogv 6.4 s, 713 × 648; 1.27 MB
  
• Harvesting-Candidate-Genes-Responsible-for-Serious-Adverse-Drug-Reactions-from-a-Chemical-Protein-pcbi.1000441.s010.ogv 9.0 s, 640 × 476; 7.68 MB
  
• Harvesting-Candidate-Genes-Responsible-for-Serious-Adverse-Drug-Reactions-from-a-Chemical-Protein-pcbi.1000441.s011.ogv 9.0 s, 640 × 476; 7.67 MB
  
• High-Affinity-Antigen-Recognition-of-the-Dual-Specific-Variants-of-Herceptin-Is-Entropy-Driven-in-pone.0017887.s001.ogv 7.4 s, 640 × 480; 424 KB
  
• 
  HK CWB 香港中央圖書館 HKCL 聯校科學展覽 Joint School Science Exhibition JSSE 分子建模 Molecular model Aug 2018 SSG 03.jpg 3,264 × 2,448; 2.13 MB
  
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  HK CWB 香港中央圖書館 HKCL 聯校科學展覽 Joint School Science Exhibition JSSE 分子建模 Molecular model Aug 2018 SSG 地球儀 Globe.jpg 2,448 × 3,264; 2.44 MB
  
• How-does-heparin-prevent-the-pH-inactivation-of-cathepsin-B-Allosteric-mechanism-elucidated-by-1471-2164-11-S5-S5-S5.ogv 3.2 s, 667 × 457; 3.51 MB
  
• How-does-heparin-prevent-the-pH-inactivation-of-cathepsin-B-Allosteric-mechanism-elucidated-by-1471-2164-11-S5-S5-S6.ogv 3.2 s, 646 × 476; 3.65 MB
  
• How-does-heparin-prevent-the-pH-inactivation-of-cathepsin-B-Allosteric-mechanism-elucidated-by-1471-2164-11-S5-S5-S7.ogv 3.2 s, 647 × 464; 3.33 MB
  
• How-does-heparin-prevent-the-pH-inactivation-of-cathepsin-B-Allosteric-mechanism-elucidated-by-1471-2164-11-S5-S5-S8.ogv 3.2 s, 648 × 470; 3.25 MB
  
• Human-enterovirus-71-subgenotype-B3-lacks-coxsackievirus-A16-like-neurovirulence-in-mice-infection-1743-422X-2-74-S1.ogv 16 s, 320 × 240; 328 KB
  
• 
  Human-sized model of isotactic polypropylene.jpg 3,000 × 4,000; 3.85 MB
  
• Identification-of-the-Allosteric-Regulatory-Site-of-Insulysin-pone.0020864.s012.ogv 4.0 s, 1,280 × 720; 669 KB
  
• Identification-of-the-Allosteric-Regulatory-Site-of-Insulysin-pone.0020864.s013.ogv 4.0 s, 1,280 × 720; 405 KB
  
• In-Silico-Investigation-of-Conformational-Motions-in-Superfamily-2-Helicase-Proteins-pone.0021809.s001.ogv 5.0 s, 872 × 480; 1.78 MB
  
• In-Silico-Investigation-of-Conformational-Motions-in-Superfamily-2-Helicase-Proteins-pone.0021809.s002.ogv 5.0 s, 872 × 480; 1.33 MB
  
• In-Silico-Investigation-of-Conformational-Motions-in-Superfamily-2-Helicase-Proteins-pone.0021809.s003.ogv 5.0 s, 872 × 480; 2.19 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s028.ogv 5.3 s, 400 × 400; 43 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s029.ogv 14 s, 800 × 400; 192 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s030.ogv 27 s, 400 × 400; 17.11 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s031.ogv 10 s, 600 × 600; 13.67 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s032.ogv 2.9 s, 240 × 240; 90 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s033.ogv 8.0 s, 800 × 800; 756 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s034.ogv 15 s, 800 × 800; 1.33 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s035.ogv 8.0 s, 1,328 × 320; 1.08 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s036.ogv 8.0 s, 1,328 × 320; 1.4 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s037.ogv 8.0 s, 1,328 × 320; 1.38 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s038.ogv 5.6 s, 800 × 800; 422 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s039.ogv 28 s, 1,600 × 800; 1.02 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s040.ogv 8.1 s, 512 × 512; 2.38 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s041.ogv 5.5 s, 800 × 800; 676 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s042.ogv 6.5 s, 800 × 800; 897 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s043.ogv 12 s, 400 × 400; 280 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s044.ogv 28 s, 400 × 400; 1.37 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s045.ogv 28 s, 400 × 400; 1.34 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s046.ogv 8.0 s, 400 × 208; 804 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s047.ogv 16 s, 400 × 512; 712 KB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s048.ogv 6.5 s, 1,024 × 768; 1.37 MB
  
• In-Silico-Reconstitution-of-Actin-Based-Symmetry-Breaking-and-Motility-pbio.1000201.s049.ogv 21 s, 400 × 400; 1.27 MB
  
• Inside-out-Ca2+-signalling-prompted-by-STIM1-conformational-switch-ncomms8826-s2.ogv 5.3 s, 1,160 × 448; 559 KB
  
• Inside-out-Ca2+-signalling-prompted-by-STIM1-conformational-switch-ncomms8826-s3.ogv 5.0 s, 752 × 564; 208 KB
  
• Inside-out-Ca2+-signalling-prompted-by-STIM1-conformational-switch-ncomms8826-s4.ogv 5.0 s, 1,004 × 504; 288 KB
  
• Inside-out-Ca2+-signalling-prompted-by-STIM1-conformational-switch-ncomms8826-s5.ogv 6.0 s, 1,176 × 592; 89 KB
  
• Interaction-between-the-C-terminal-region-of-human-myelin-basic-protein-and-calmodulin-analysis-of-1472-6807-8-10-S2.ogv 4.2 s, 360 × 240; 354 KB
  
• Intuitive-representation-of-surface-properties-of-biomolecules-using-BioBlender-1471-2105-13-S4-S16-S1.ogv 19 s, 768 × 576; 7.3 MB
  
• IPET-and-FETR-Experimental-Approach-for-Studying-Molecular-Structure-Dynamics-by-Cryo-Electron-pone.0030249.s026.ogv 7.9 s, 640 × 480; 1.64 MB
  
• IPET-and-FETR-Experimental-Approach-for-Studying-Molecular-Structure-Dynamics-by-Cryo-Electron-pone.0030249.s027.ogv 6.5 s, 702 × 723; 2.73 MB
  
• IPET-and-FETR-Experimental-Approach-for-Studying-Molecular-Structure-Dynamics-by-Cryo-Electron-pone.0030249.s028.ogv 6.5 s, 600 × 600; 1.21 MB
  
• Kissing-G-Domains-of-MnmE-Monitored-by-X-Ray-Crystallography-and-Pulse-Electron-Paramagnetic-pbio.1000212.s006.ogv 2.7 s, 1,067 × 641; 760 KB
  
• Large-Scale-Conformational-Changes-of-Trypanosoma-cruzi-Proline-Racemase-Predicted-by-Accelerated-pcbi.1002178.s004.ogv 21 s, 948 × 566; 961 KB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s2.ogv 21 s, 1,280 × 960; 3.35 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s3.ogv 11 s, 1,280 × 960; 10.98 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s4.ogv 11 s, 1,280 × 960; 16.25 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s5.ogv 20 s, 1,280 × 960; 30.4 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s6.ogv 7.2 s, 1,280 × 960; 3.2 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s7.ogv 7.2 s, 1,280 × 960; 4.08 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s8.ogv 7.2 s, 1,280 × 960; 4.82 MB
  
• Lattice-free-prediction-of-three-dimensional-structure-of-programmed-DNA-assemblies-ncomms6578-s9.ogv 28 s, 1,280 × 960; 43.59 MB
  
• 
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• Mapping-the-Conformational-Dynamics-and-Pathways-of-Spontaneous-Steric-Zipper-Peptide-pone.0019129.s010.ogv 20 s, 670 × 834; 5.03 MB
  
• Mechanical-Network-in-Titin-Immunoglobulin-from-Force-Distribution-Analysis-pcbi.1000306.s012.ogv 10 s, 640 × 480; 3.45 MB
  
• Mechanochemical-Modeling-of-Dynamic-Microtubule-Growth-Involving-Sheet-to-Tube-Transition-pone.0029049.s002.ogv 39 s, 420 × 240; 2.63 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s007.ogv 13 s, 528 × 480; 5.12 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s008.ogv 13 s, 528 × 480; 5.05 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s009.ogv 13 s, 528 × 480; 2.42 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s010.ogv 4.2 s, 528 × 480; 1.79 MB
  
• Microsecond-Molecular-Dynamics-Simulations-of-Intrinsically-Disordered-Proteins-Involved-in-the-pone.0027371.s001.ogv 0.0 s, 464 × 416; 17.8 MB
  
• Microsecond-Molecular-Dynamics-Simulations-of-Intrinsically-Disordered-Proteins-Involved-in-the-pone.0027371.s002.ogv 0.0 s, 480 × 416; 6.67 MB
  
• Modeling-a-New-Water-Channel-That-Allows-SET9-to-Dimethylate-p53-pone.0019856.s005.ogv 10 s, 656 × 624; 1.87 MB
  
• Modeling-and-Dynamics-of-the-Inward-Facing-State-of-a-Na+Cl−-Dependent-Neurotransmitter-Transporter-pcbi.1000905.s005.ogv 14 s, 350 × 452; 4.04 MB
  
• Modeling-and-Dynamics-of-the-Inward-Facing-State-of-a-Na+Cl−-Dependent-Neurotransmitter-Transporter-pcbi.1000905.s006.ogv 14 s, 350 × 466; 4.2 MB
  
• Modeling-Signal-Propagation-Mechanisms-and-Ligand-Based-Conformational-Dynamics-of-the-Hsp90-pcbi.1000323.s007.ogv 3.3 s, 640 × 480; 459 KB
  
• Modeling-Signal-Propagation-Mechanisms-and-Ligand-Based-Conformational-Dynamics-of-the-Hsp90-pcbi.1000323.s008.ogv 3.3 s, 640 × 480; 407 KB
  
• Molecular-Architecture-of-the-Human-Mediator–RNA-Polymerase-II–TFIIF-Assembly-pbio.1000603.s016.ogv 1 min 2 s, 720 × 480; 23.48 MB
  
• Molecular-Basis-for-the-Dual-Function-of-Eps8-on-Actin-DynamicsBundling-and-Capping-pbio.1000387.s011.ogv 6.0 s, 276 × 234; 27 KB
  
• Molecular-Basis-for-the-Dual-Function-of-Eps8-on-Actin-DynamicsBundling-and-Capping-pbio.1000387.s012.ogv 6.0 s, 276 × 234; 24 KB
  
• Molecular-Basis-for-the-Dual-Function-of-Eps8-on-Actin-DynamicsBundling-and-Capping-pbio.1000387.s013.ogv 2.8 s, 292 × 256; 77 KB
  
• Molecular-Basis-for-the-Dual-Function-of-Eps8-on-Actin-DynamicsBundling-and-Capping-pbio.1000387.s014.ogv 2.5 s, 292 × 254; 125 KB