Category:Protein folding

Subcategories

This category has the following 7 subcategories, out of 7 total.

Media in category "Protein folding"

The following 200 files are in this category, out of 254 total.

• 
  1X9J.png 640 × 434; 364 KB
  
• 
  3bq.ent.pdb.png 385 × 388; 59 KB
  
• 
  41594 2023 1201 Fig4.webp 1,826 × 2,181; 513 KB
  
• 
  41594 2023 1201 FigE10 Fig15.webp 2,100 × 737; 117 KB
  
• 
  41594 2023 1201 FigE2 Fig7.webp 2,086 × 2,268; 217 KB
  
• 
  41594 2023 1201 FigE3 Fig8.webp 1,805 × 1,989; 207 KB
  
• 
  41594 2023 1201 FigE4 Fig9.webp 2,105 × 1,886; 417 KB
  
• 
  41594 2023 1201 FigE5 Fig10.webp 1,858 × 2,712; 429 KB
  
• 
  41594 2023 1201 FigE6 Fig11.webp 2,072 × 2,189; 364 KB
  
• 
  41594 2023 1201 FigE7 Fig12.webp 2,079 × 1,678; 325 KB
  
• 
  41594 2023 1201 FigE8 Fig13.webp 1,651 × 2,031; 378 KB
  
• 
  41594 2023 1201 FigE9 Fig14.webp 2,086 × 1,531; 287 KB
  
• 
  4oq9 chainA jellyroll.png 1,024 × 1,024; 271 KB
  
• 
  A model of DBH active site based on PHM.jpg 360 × 670; 114 KB
  
• A replica exchange molecular dynamics simulation of the folding of.webm 1 min 40 s, 3,872 × 2,142; 47.25 MB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s006.ogv 7.3 s, 288 × 256; 41 KB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s007.ogv 7.2 s, 556 × 500; 81 KB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s008.ogv 22 s, 560 × 500; 275 KB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s009.ogv 15 s, 608 × 496; 251 KB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s010.ogv 43 s, 1,110 × 1,000; 1.21 MB
  
• A-Customized-Light-Sheet-Microscope-to-Measure-Spatio-Temporal-Protein-Dynamics-in-Small-Model-pone.0127869.s011.ogv 36 s, 594 × 822; 1.07 MB
  
• A-SEL1L-Mutation-Links-a-Canine-Progressive-Early-Onset-Cerebellar-Ataxia-to-the-Endoplasmic-pgen.1002759.s007.ogv 1 min 37 s, 640 × 480; 19.73 MB
  
• A-SEL1L-Mutation-Links-a-Canine-Progressive-Early-Onset-Cerebellar-Ataxia-to-the-Endoplasmic-pgen.1002759.s008.ogv 1 min 56 s, 640 × 480; 23.41 MB
  
• A-SEL1L-Mutation-Links-a-Canine-Progressive-Early-Onset-Cerebellar-Ataxia-to-the-Endoplasmic-pgen.1002759.s009.ogv 1 min 48 s, 640 × 480; 18.26 MB
  
• 
  AAAA.jpg 240 × 240; 21 KB
  
• 
  AAAA1.jpg 240 × 240; 20 KB
  
• 
  AaHIT1 3D residue19-88.JPG 261 × 279; 21 KB
  
• 
  ACBP MSM from Folding@home.tiff 3,036 × 1,817; 1.1 MB
  
• 
  Alpha helix neg60 neg45 topview.png 572 × 566; 96 KB
  
• 
  Alpha sheet bonding schematic-color.svg 2,138 × 2,181; 50 KB
  
• 
  Alpha strand 50 50 vertical.png 287 × 820; 63 KB
  
• 
  Alpha strand 50 50.png 820 × 287; 64 KB
  
• An-ALS-Linked-Mutant-SOD1-Produces-a-Locomotor-Defect-Associated-with-Aggregation-and-Synaptic-pgen.1000350.s013.ogv 29 s, 640 × 480; 1.04 MB
  
• An-ALS-Linked-Mutant-SOD1-Produces-a-Locomotor-Defect-Associated-with-Aggregation-and-Synaptic-pgen.1000350.s014.ogv 30 s, 480 × 360; 425 KB
  
• An-ALS-Linked-Mutant-SOD1-Produces-a-Locomotor-Defect-Associated-with-Aggregation-and-Synaptic-pgen.1000350.s015.ogv 30 s, 480 × 360; 366 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s008.ogv 57 s, 1,920 × 1,080; 570 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s009.ogv 54 s, 1,920 × 1,080; 540 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s010.ogv 54 s, 1,920 × 1,080; 530 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s011.ogv 54 s, 1,920 × 1,080; 522 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s012.ogv 36 s, 1,920 × 1,080; 364 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s013.ogv 54 s, 1,920 × 1,080; 545 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s014.ogv 21 s, 1,920 × 1,080; 256 KB
  
• An-Automatic-Refolding-Apparatus-for-Preparative-Scale-Protein-Production-pone.0045891.s015.ogv 39 s, 1,920 × 1,080; 400 KB
  
• An-Essential-Nonredundant-Role-for-Mycobacterial-DnaK-in-Native-Protein-Folding-pgen.1004516.s017.ogv 11 s, 750 × 500; 417 KB
  
• An-Essential-Nonredundant-Role-for-Mycobacterial-DnaK-in-Native-Protein-Folding-pgen.1004516.s018.ogv 16 s, 500 × 500; 293 KB
  
• An-Essential-Nonredundant-Role-for-Mycobacterial-DnaK-in-Native-Protein-Folding-pgen.1004516.s019.ogv 10 s, 1,050 × 350; 177 KB
  
• An-Essential-Nonredundant-Role-for-Mycobacterial-DnaK-in-Native-Protein-Folding-pgen.1004516.s020.ogv 17 s, 300 × 300; 88 KB
  
• An-Essential-Nonredundant-Role-for-Mycobacterial-DnaK-in-Native-Protein-Folding-pgen.1004516.s021.ogv 16 s, 300 × 300; 63 KB
  
• 
  Aquagliceroporina.png 604 × 338; 159 KB
  
• 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
  
• ATP-Dependent-Rotational-Motion-of-Group-II-Chaperonin-Observed-by-X-ray-Single-Molecule-Tracking-pone.0064176.s011.ogv 7.5 s, 640 × 480; 327 KB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s010.ogv 59 s, 720 × 480; 10.61 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s011.ogv 1 min 2 s, 720 × 480; 5.63 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s012.ogv 2 min 22 s, 720 × 480; 5.1 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s013.ogv 6 min 12 s, 720 × 480; 8.99 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s014.ogv 5 min 43 s, 720 × 480; 6.77 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s015.ogv 1 min 17 s, 720 × 480; 7.63 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s016.ogv 38 s, 720 × 480; 2.16 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s017.ogv 2 min 51 s, 720 × 480; 5.91 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s018.ogv 6 min 22 s, 720 × 480; 8.99 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s019.ogv 4 min 50 s, 720 × 480; 5.61 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s020.ogv 8.5 s, 720 × 480; 863 KB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s021.ogv 39 s, 720 × 480; 2.83 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s022.ogv 2 min 52 s, 720 × 480; 4.65 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s023.ogv 8 min 13 s, 720 × 480; 9.05 MB
  
• BCLFold---De-Novo-Prediction-of-Complex-and-Large-Protein-Topologies-by-Assembly-of-Secondary-pone.0049240.s024.ogv 5 min 5 s, 720 × 480; 4.79 MB
  
• 
  Beta sheet bonding antiparallel-color.svg 1,151 × 3,855; 15 KB
  
• 
  Beta sheet bonding parallel-color.svg 1,151 × 3,855; 49 KB
  
• 
  Beta-meander1.png 393 × 255; 24 KB
  
• 
  BetaPleatedSheetProtein.png 610 × 422; 38 KB
  
• Bisphenol-A-Binds-to-the-Local-Anesthetic-Receptor-Site-to-Block-the-Human-Cardiac-Sodium-Channel-pone.0041667.s002.ogv 0.0 s, 503 × 332; 6.25 MB
  
• Bisphenol-A-Binds-to-the-Local-Anesthetic-Receptor-Site-to-Block-the-Human-Cardiac-Sodium-Channel-pone.0041667.s003.ogv 0.0 s, 503 × 332; 6.27 MB
  
• Bisphenol-A-Binds-to-the-Local-Anesthetic-Receptor-Site-to-Block-the-Human-Cardiac-Sodium-Channel-pone.0041667.s004.ogv 17 s, 533 × 440; 7.91 MB
  
• Bisphenol-A-Binds-to-the-Local-Anesthetic-Receptor-Site-to-Block-the-Human-Cardiac-Sodium-Channel-pone.0041667.s005.ogv 0.0 s, 533 × 440; 7.26 MB
  
• 
  Bj1.png 902 × 536; 371 KB
  
• 
  Bj2.png 452 × 611; 110 KB
  
• 
  Bj3.png 412 × 544; 69 KB
  
• 
  BPTI seq ribbon sticks.jpg 1,024 × 768; 246 KB
  
• 
  C-FLIPl.png 1,781 × 1,283; 306 KB
  
• 
  CalmodulinConformation.png 700 × 671; 149 KB
  
• 
  Chaperonin 1AON.png 1,956 × 850; 1.55 MB
  
• 
  Circular-solenoid-domain-sketch.png 662 × 582; 53 KB
  
• Cochleates-Derived-from-Vibrio-cholerae-O1-Proteoliposomes-The-Impact-of-Structure-Transformation-pone.0046461.s001.ogv 27 s, 384 × 288; 117 KB
  
• 
  Comparison of ferritin and transferrin.png 1,148 × 580; 436 KB
  
• Computational-and-Experimental-Characterization-of-dVHL-Establish-a-Drosophila-Model-of-VHL-Syndrome-pone.0109864.s005.ogv 8.7 s, 960 × 720; 1.7 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
  
• Coupled-Protein-Diffusion-and-Folding-in-the-Cell-pone.0113040.s002.ogv 4.0 s, 103 × 124; 18 KB
  
• De-Novo-Generation-of-Infectious-Prions-In-Vitro-Produces-a-New-Disease-Phenotype-ppat.1000421.s004.ogv 3 min 2 s, 320 × 240; 14.98 MB
  
• De-Novo-Generation-of-Infectious-Prions-In-Vitro-Produces-a-New-Disease-Phenotype-ppat.1000421.s005.ogv 3 min 19 s, 320 × 240; 17.24 MB
  
• Deciphering-the-Structure-Growth-and-Assembly-of-Amyloid-Like-Fibrils-Using-High-Speed-Atomic-Force-pone.0013240.s003.ogv 42 s, 128 × 128; 908 KB
  
• Deciphering-the-Structure-Growth-and-Assembly-of-Amyloid-Like-Fibrils-Using-High-Speed-Atomic-Force-pone.0013240.s004.ogv 3.0 s, 128 × 128; 39 KB
  
• Deciphering-the-Structure-Growth-and-Assembly-of-Amyloid-Like-Fibrils-Using-High-Speed-Atomic-Force-pone.0013240.s005.ogv 39 s, 128 × 128; 993 KB
  
• Development-of-Cysteine-Free-Fluorescent-Proteins-for-the-Oxidative-Environment-pone.0037551.s004.ogv 8.9 s, 512 × 512; 3.85 MB
  
• 
  Diacylglycerol lipase α (via AlphaFold2, ColabFold, and PyMol).png 3,016 × 1,566; 715 KB
  
• 
  Diacylglycerol lipase β (via AlphaFold2, ColabFold, and PyMol).png 3,016 × 1,566; 695 KB
  
• Diffusion-Crowding-&-Protein-Stability-in-a-Dynamic-Molecular-Model-of-the-Bacterial-Cytoplasm-pcbi.1000694.s014.ogv 6.0 s, 330 × 330; 4 KB
  
• Diffusion-Crowding-&-Protein-Stability-in-a-Dynamic-Molecular-Model-of-the-Bacterial-Cytoplasm-pcbi.1000694.s015.ogv 6.0 s, 330 × 330; 4 KB
  
• 
  Dimer of trimer 1YR3.png 460 × 400; 141 KB
  
• 
  DisulfideBondFormation.png 786 × 242; 3 KB
  
• 
  DisulfideBondFormation.svg 957 × 407; 50 KB
  
• Divergent-Effects-of-PERK-and-IRE1-Signaling-on-Cell-Viability-pone.0004170.s004.ogv 39 s, 696 × 260; 12.69 MB
  
• Divergent-Effects-of-PERK-and-IRE1-Signaling-on-Cell-Viability-pone.0004170.s005.ogv 40 s, 696 × 260; 9.61 MB
  
• Divergent-Effects-of-PERK-and-IRE1-Signaling-on-Cell-Viability-pone.0004170.s006.ogv 40 s, 696 × 260; 19.67 MB
  
• 
  DsRBD.png 596 × 638; 255 KB
  
• Dual-Chaperone-Role-of-the-C-Terminal-Propeptide-in-Folding-and-Oligomerization-of-the-Pore-Forming-ppat.1002135.s004.ogv 30 s, 640 × 480; 10.07 MB
  
• Dual-Chaperone-Role-of-the-C-Terminal-Propeptide-in-Folding-and-Oligomerization-of-the-Pore-Forming-ppat.1002135.s005.ogv 42 s, 640 × 480; 13.16 MB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s007.ogv 5.0 s, 512 × 512; 117 KB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s008.ogv 5.0 s, 512 × 512; 28 KB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s009.ogv 5.0 s, 512 × 512; 16 KB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s010.ogv 5.0 s, 512 × 504; 77 KB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s011.ogv 56 s, 800 × 602; 2.54 MB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s012.ogv 1 min 16 s, 800 × 602; 3.22 MB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s013.ogv 25 s, 800 × 602; 1.55 MB
  
• Dysferlin-Peptides-Reallocate-Mutated-Dysferlin-Thereby-Restoring-Function-pone.0049603.s014.ogv 52 s, 896 × 672; 2.63 MB
  
• 
  Energy Landscape.jpg 571 × 380; 90 KB
  
• 
  Estructura proteínas.png 474 × 536; 26 KB
  
• 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
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s004.ogv 14 s, 694 × 520; 3.95 MB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s005.ogv 14 s, 694 × 520; 793 KB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s006.ogv 14 s, 694 × 520; 5.08 MB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s007.ogv 14 s, 694 × 520; 666 KB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s008.ogv 14 s, 694 × 520; 5.87 MB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s009.ogv 14 s, 694 × 520; 818 KB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s010.ogv 14 s, 694 × 520; 4.67 MB
  
• Experimental-and-Computational-Analysis-of-Polyglutamine-Mediated-Cytotoxicity-pcbi.1000944.s011.ogv 14 s, 694 × 520; 340 KB
  
• Exploring-the-Universe-of-Protein-Structures-beyond-the-Protein-Data-Bank-pcbi.1000957.s008.ogv 0.0 s, 656 × 832; 6.59 MB
  
• Fibronectin-Unfolding-Revisited-Modeling-Cell-Traction-Mediated-Unfolding-of-the-Tenth-Type-III-pone.0002373.s004.ogv 10 s, 640 × 240; 996 KB
  
• Fibronectin-Unfolding-Revisited-Modeling-Cell-Traction-Mediated-Unfolding-of-the-Tenth-Type-III-pone.0002373.s005.ogv 10 s, 640 × 240; 987 KB
  
• Fibronectin-Unfolding-Revisited-Modeling-Cell-Traction-Mediated-Unfolding-of-the-Tenth-Type-III-pone.0002373.s006.ogv 13 s, 640 × 240; 993 KB
  
• 
  Folding energy diagram terbidium4.jpg 507 × 583; 29 KB
  
• 
  Folding Funnel.svg 167 × 255; 10 KB
  
• Force-Induced-Unfolding-Simulations-of-the-Human-Notch1-Negative-Regulatory-Region-Possible-Roles-pone.0022837.s003.ogv 0.0 s, 928 × 832; 22.1 MB
  
• FRET-Assisted-Determination-of-CLN3-Membrane-Topology-pone.0102593.s001.ogv 25 s, 1,536 × 512; 5.26 MB
  
• 
  Hexosaminidase A (heterodimer, with van der Waals interactions).jpg 700 × 400; 220 KB
  
• 
  HLA-A*02 protein structure.jpg 500 × 500; 44 KB
  
• How-Leiomodin-and-Tropomodulin-use-a-common-fold-for-different-actin-assembly-functions-ncomms9314-s2.ogv 5.0 s, 500 × 500; 2.37 MB
  
• How-Leiomodin-and-Tropomodulin-use-a-common-fold-for-different-actin-assembly-functions-ncomms9314-s3.ogv 5.0 s, 500 × 500; 1.94 MB
  
• How-Leiomodin-and-Tropomodulin-use-a-common-fold-for-different-actin-assembly-functions-ncomms9314-s4.ogv 15 s, 700 × 600; 7.62 MB
  
• How-Leiomodin-and-Tropomodulin-use-a-common-fold-for-different-actin-assembly-functions-ncomms9314-s5.ogv 9.3 s, 584 × 600; 1.79 MB
  
• 
  HP Lattice Protein Model Schematic.png 720 × 540; 49 KB
  
• 
  I-TASSER predicted protein fold of Fam188a.gif 535 × 535; 25 KB
  
• 
  Isomerization pathway in bacteria (mechanism).jpg 599 × 414; 20 KB
  
• 
  Isomerization pathway in bacteria(mechanism).jpg 541 × 372; 17 KB
  
• 
  KSI homodimer.png 640 × 434; 119 KB
  
• 
  Linear-solenoid-domain-sketch.png 662 × 582; 55 KB
  
• Magnetotactic-molecular-architectures-from-self-assembly-of-β-peptide-foldamers-ncomms9747-s2.ogv 15 s, 640 × 480; 1.68 MB
  
• Magnetotactic-molecular-architectures-from-self-assembly-of-β-peptide-foldamers-ncomms9747-s3.ogv 18 s, 640 × 480; 357 KB
  
• Magnetotactic-molecular-architectures-from-self-assembly-of-β-peptide-foldamers-ncomms9747-s4.ogv 30 s, 640 × 480; 5.68 MB
  
• 
  Main protein structure levels cs.svg 463 × 808; 252 KB
  
• Mapping-the-Conformational-Dynamics-and-Pathways-of-Spontaneous-Steric-Zipper-Peptide-pone.0019129.s010.ogv 20 s, 670 × 834; 5.03 MB
  
• 
  MDC1-tandem-BRCT-domains-with-ligand.png 766 × 688; 104 KB
  
• Membrane-Permeabilization-by-Oligomeric-α-Synuclein-In-Search-of-the-Mechanism-pone.0014292.s001.ogv 8.6 s, 512 × 512; 1.33 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-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
  
• Native-structure-based-modeling-and-simulation-of-biomolecular-systems-per-mouse-click-12859 2014 6561 MOESM1 ESM.ogv 1 min 56 s, 1,024 × 1,024; 7.32 MB
  
• Native-structure-based-modeling-and-simulation-of-biomolecular-systems-per-mouse-click-12859 2014 6561 MOESM2 ESM.ogv 2 min 10 s, 1,024 × 1,024; 8.92 MB
  
• Native-structure-based-modeling-and-simulation-of-biomolecular-systems-per-mouse-click-12859 2014 6561 MOESM3 ESM.ogv 1 min 36 s, 1,024 × 1,024; 7.94 MB
  
• Overproduced-Brucella-abortus-PdhS-mCherry-forms-soluble-aggregates-in-Escherichia-coli-partially-1471-2180-10-248-S1.ogv 5.4 s, 1,344 × 1,024; 2.04 MB
  
• 
  Oxidative folding in eukaryotes (mechanism).jpg 538 × 441; 20 KB
  
• 
  Oxidative folding in eukaryotes(mechanism).jpg 554 × 425; 20 KB
  
• 
  Oxidative pathway in bacteria (mechanism).jpg 619 × 448; 22 KB
  
• 
  Oxidative pathway in bacteria(mechanism).jpg 548 × 381; 19 KB
  
• 
  P3 peptide 2013-10-23 17-14.jpg 504 × 504; 56 KB
  
• Physicochemical-Characterization-of-a-Thermostable-Alcohol-Dehydrogenase-from-Pyrobaculum-aerophilum-pone.0063828.s009.ogv 22 s, 640 × 480; 1.7 MB
  
• 
  Protein fold.png 373 × 266; 47 KB
  
• 
  Protein Folding 2.JPG 370 × 260; 9 KB
  
• 
  Protein folding figure-es.png 1,042 × 1,232; 204 KB
  
• 
  Protein folding figure.png 1,042 × 1,232; 271 KB
  
• 
  Protein folding schematic.png 930 × 826; 43 KB
  
• 
  Protein folding.png 994 × 440; 70 KB
  
• 
  Protein Structural changes timescale matched with NMR experiments.png 1,416 × 544; 93 KB
  
• 
  Protein-structure hy.png 396 × 540; 64 KB
  
• 
  Protein-structure uk.jpg 287 × 515; 42 KB
  
• 
  Protein-structure.png 396 × 540; 49 KB
  
• 
  ProteinStructures fr.png 566 × 1,514; 116 KB
  
• 
  ProteinStructures.gif 396 × 540; 20 KB
  
• 
  ProteinStructures.png 566 × 1,700; 161 KB
  
• 
  RACK1.png 750 × 675; 220 KB
  
• 
  Ribbon diagram depicting the crystal structure of the GPIbβ extracellular domain.png 282 × 338; 39 KB
  
• 
  Ribbon diagram representation of the folding of the protein barnase.png 570 × 859; 127 KB
  
• 
  Ribose-5-phosphate isomerase.png 662 × 333; 223 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s007.ogv 20 s, 480 × 480; 580 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s008.ogv 3.6 s, 309 × 170; 214 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s009.ogv 4.1 s, 451 × 142; 190 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s010.ogv 4.1 s, 402 × 131; 235 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s011.ogv 4.1 s, 343 × 126; 270 KB
  
• Role-of-T198-Modification-in-the-Regulation-of-p27Kip1-Protein-Stability-and-Function-pone.0017673.s012.ogv 3.6 s, 801 × 401; 2.19 MB
  
• 
  Rough ER Close up.png 1,188 × 672; 138 KB