Category:Bacterial physiology

Subcategories

This category has the following 8 subcategories, out of 8 total.

Media in category "Bacterial physiology"

The following 131 files are in this category, out of 131 total.

• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s009.ogv 40 s, 640 × 480; 5.54 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s010.ogv 20 s, 640 × 480; 368 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s011.ogv 20 s, 640 × 480; 1.16 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s012.ogv 20 s, 640 × 480; 1.01 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s013.ogv 20 s, 640 × 480; 918 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s014.ogv 20 s, 640 × 480; 783 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s015.ogv 20 s, 640 × 480; 1.28 MB
  
• A-Microscope-Automated-Fluidic-System-to-Study-Bacterial-Processes-in-Real-Time-pone.0007282.s002.ogv 8.3 s, 776 × 654; 822 KB
  
• A-Microscope-Automated-Fluidic-System-to-Study-Bacterial-Processes-in-Real-Time-pone.0007282.s003.ogv 26 s, 745 × 498; 596 KB
  
• Application-of-a-Genetically-Encoded-Biosensor-for-Live-Cell-Imaging-of-L-Valine-Production-in-pone.0085731.s002.ogv 30 s, 544 × 720; 1.67 MB
  
• Application-of-a-Genetically-Encoded-Biosensor-for-Live-Cell-Imaging-of-L-Valine-Production-in-pone.0085731.s003.ogv 30 s, 584 × 720; 1.69 MB
  
• Application-of-a-Genetically-Encoded-Biosensor-for-Live-Cell-Imaging-of-L-Valine-Production-in-pone.0085731.s004.ogv 24 s, 776 × 720; 1.54 MB
  
• Application-of-a-Genetically-Encoded-Biosensor-for-Live-Cell-Imaging-of-L-Valine-Production-in-pone.0085731.s005.ogv 29 s, 720 × 720; 1.26 MB
  
• Application-of-a-Genetically-Encoded-Biosensor-for-Live-Cell-Imaging-of-L-Valine-Production-in-pone.0085731.s006.ogv 32 s, 888 × 720; 1.39 MB
  
• Bacillus-subtilis-MreB-Orthologs-Self-Organize-into-Filamentous-Structures-underneath-the-Cell-pone.0027035.s001.ogv 9.0 s, 166 × 168; 53 KB
  
• Bacillus-subtilis-MreB-Orthologs-Self-Organize-into-Filamentous-Structures-underneath-the-Cell-pone.0027035.s002.ogv 9.0 s, 223 × 228; 32 KB
  
• Bacillus-subtilis-MreB-Orthologs-Self-Organize-into-Filamentous-Structures-underneath-the-Cell-pone.0027035.s003.ogv 14 s, 206 × 224; 97 KB
  
• Bacillus-subtilis-MreB-Orthologs-Self-Organize-into-Filamentous-Structures-underneath-the-Cell-pone.0027035.s004.ogv 8.0 s, 315 × 294; 448 KB
  
• Bacterial-growth-and-form-under-mechanical-compression-srep11367-s2.ogv 12 s, 400 × 340; 3.39 MB
  
• Bacterial-growth-and-form-under-mechanical-compression-srep11367-s3.ogv 7.0 s, 400 × 340; 230 KB
  
• Bacterial-growth-and-form-under-mechanical-compression-srep11367-s4.ogv 8.0 s, 788 × 460; 835 KB
  
• Bacterial-growth-and-form-under-mechanical-compression-srep11367-s5.ogv 1.2 s, 570 × 300; 484 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s001.ogv 12 s, 134 × 137; 104 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s002.ogv 1.8 s, 818 × 716; 829 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s003.ogv 5.6 s, 1,000 × 484; 1.09 MB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s004.ogv 12 s, 218 × 116; 55 KB
  
• Chromosome-Segregation-Impacts-on-Cell-Growth-and-Division-Site-Selection-in-Corynebacterium-pone.0055078.s002.ogv 5.9 s, 583 × 976; 1.25 MB
  
• Chromosome-Segregation-Impacts-on-Cell-Growth-and-Division-Site-Selection-in-Corynebacterium-pone.0055078.s003.ogv 12 s, 784 × 736; 556 KB
  
• Chromosome-Segregation-Impacts-on-Cell-Growth-and-Division-Site-Selection-in-Corynebacterium-pone.0055078.s004.ogv 8.5 s, 480 × 555; 527 KB
  
• Chromosome-Segregation-Impacts-on-Cell-Growth-and-Division-Site-Selection-in-Corynebacterium-pone.0055078.s005.ogv 4.5 s, 487 × 829; 433 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s009.ogv 15 s, 480 × 240; 301 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s010.ogv 15 s, 60 × 30; 38 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s011.ogv 31 s, 60 × 30; 32 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s012.ogv 20 s, 60 × 30; 32 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s013.ogv 6.7 s, 60 × 30; 12 KB
  
• Concerted-Spatio-Temporal-Dynamics-of-Imported-DNA-and-ComE-DNA-Uptake-Protein-during-Gonococcal-ppat.1004043.s014.ogv 7.0 s, 100 × 50; 24 KB
  
• Coordinated-Long-Range-Solid-Substrate-Movement-of-the-Purple-Photosynthetic-Bacterium-Rhodobacter-pone.0019646.s001.ogv 1 min 30 s, 640 × 480; 6.49 MB
  
• Deformation-of-Filamentous-Escherichia-coli-Cells-in-a-Microfluidic-Device-A-New-Technique-to-Study-pone.0083775.s009.ogv 4.2 s, 1,392 × 1,040; 1.98 MB
  
• Deformation-of-Filamentous-Escherichia-coli-Cells-in-a-Microfluidic-Device-A-New-Technique-to-Study-pone.0083775.s010.ogv 1.4 s, 1,392 × 1,040; 127 KB
  
• Deformation-of-Filamentous-Escherichia-coli-Cells-in-a-Microfluidic-Device-A-New-Technique-to-Study-pone.0083775.s011.ogv 1 min 40 s, 508 × 508; 782 KB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s001.ogv 5.7 s, 600 × 600; 1.44 MB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s002.ogv 7.0 s, 600 × 600; 1.29 MB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s003.ogv 1.2 s, 148 × 148; 13 KB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s004.ogv 3.7 s, 200 × 200; 45 KB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s005.ogv 12 s, 800 × 600; 1,012 KB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s006.ogv 5.5 s, 248 × 448; 428 KB
  
• Exopolysaccharide-Independent-Social-Motility-of-Myxococcusxanthus-pone.0016102.s007.ogv 5.0 s, 248 × 448; 575 KB
  
• Francisella-tularensis-IglG-Belongs-to-a-Novel-Family-of-PAAR-Like-T6SS-Proteins-and-Harbors-a-ppat.1005821.s018.ogv 41 s, 669 × 834; 9.71 MB
  
• FtsZ-Placement-in-Nucleoid-Free-Bacteria-pone.0091984.s008.ogv 1.8 s, 141 × 179; 9 KB
  
• Genomic-and-Metabolomic-Insights-into-the-Natural-Product-Biosynthetic-Diversity-of-a-Feral-Hog-pone.0090124.s021.ogv 24 s, 640 × 480; 3.88 MB
  
• Glitter-Like-Iridescence-within-the-Bacteroidetes-Especially-Cellulophaga-spp.-Optical-Properties-pone.0052900.s001.ogv 8.6 s, 1,392 × 1,040; 11.97 MB
  
• Glitter-Like-Iridescence-within-the-Bacteroidetes-Especially-Cellulophaga-spp.-Optical-Properties-pone.0052900.s002.ogv 3.0 s, 1,392 × 1,040; 4.51 MB
  
• Glitter-Like-Iridescence-within-the-Bacteroidetes-Especially-Cellulophaga-spp.-Optical-Properties-pone.0052900.s003.ogv 7.1 s, 1,280 × 1,024; 582 KB
  
• Influence-of-Magnetic-Fields-on-Magneto-Aerotaxis-pone.0101150.s013.ogv 44 s, 640 × 480; 1.53 MB
  
• Initial-Characterization-of-the-FlgE-Hook-High-Molecular-Weight-Complex-of-Borrelia-burgdorferi-pone.0098338.s001.ogv 40 s, 640 × 480; 3.76 MB
  
• Interplay-of-the-SerineThreonine-Kinase-StkP-and-the-Paralogs-DivIVA-and-GpsB-in-Pneumococcal-Cell-pgen.1004275.s018.ogv 10 s, 1,064 × 878; 85 KB
  
• Live-Cell-Imaging-of-Germination-and-Outgrowth-of-Individual-Bacillus-subtilis-Spores-the-Effect-of-pone.0058972.s002.ogv 24 s, 696 × 520; 3.36 MB
  
• Live-Cell-Imaging-of-Germination-and-Outgrowth-of-Individual-Bacillus-subtilis-Spores-the-Effect-of-pone.0058972.s003.ogv 22 s, 696 × 520; 4.1 MB
  
• Live-Cell-Imaging-of-Germination-and-Outgrowth-of-Individual-Bacillus-subtilis-Spores-the-Effect-of-pone.0058972.s004.ogv 24 s, 634 × 484; 1.07 MB
  
• Live-Cell-Imaging-of-Germination-and-Outgrowth-of-Individual-Bacillus-subtilis-Spores-the-Effect-of-pone.0058972.s005.ogv 24 s, 682 × 491; 1.61 MB
  
• Live-Cell-Imaging-of-Germination-and-Outgrowth-of-Individual-Bacillus-subtilis-Spores-the-Effect-of-pone.0058972.s006.ogv 24 s, 647 × 497; 3.62 MB
  
• Live-Cell-Imaging-Reveals-Novel-Functions-of-Salmonella-enterica-SPI2-T3SS-Effector-Proteins-in-pone.0115423.s028.ogv 6.4 s, 450 × 375; 99 KB
  
• Mannose-Binding-Lectin-Inhibits-the-Motility-of-Pathogenic-Salmonella-by-Affecting-the-Driving-pone.0154165.s005.ogv 6.0 s, 315 × 210; 551 KB
  
• Mannose-Binding-Lectin-Inhibits-the-Motility-of-Pathogenic-Salmonella-by-Affecting-the-Driving-pone.0154165.s006.ogv 6.0 s, 324 × 224; 402 KB
  
• Mannose-Binding-Lectin-Inhibits-the-Motility-of-Pathogenic-Salmonella-by-Affecting-the-Driving-pone.0154165.s007.ogv 5.9 s, 587 × 396; 488 KB
  
• Mannose-Binding-Lectin-Inhibits-the-Motility-of-Pathogenic-Salmonella-by-Affecting-the-Driving-pone.0154165.s009.ogv 30 s, 50 × 50; 1.31 MB
  
• Memory-and-Fitness-Optimization-of-Bacteria-under-Fluctuating-Environments-pgen.1004556.s005.ogv 6.1 s, 500 × 499; 569 KB
  
• Memory-and-Fitness-Optimization-of-Bacteria-under-Fluctuating-Environments-pgen.1004556.s006.ogv 12 s, 535 × 400; 1.68 MB
  
• Modeling-E.-coli-Tumbles-by-Rotational-Diffusion.-Implications-for-Chemotaxis-pone.0035412.s001.ogv 8.8 s, 272 × 236; 738 KB
  
• Multicellular-Computing-Using-Conjugation-for-Wiring-pone.0065986.s010.ogv 22 s, 640 × 480; 7.46 MB
  
• Multicellular-Computing-Using-Conjugation-for-Wiring-pone.0065986.s011.ogv 22 s, 640 × 480; 3.51 MB
  
• Multiple-Peptidoglycan-Modification-Networks-Modulate-Helicobacter-pylori's-Cell-Shape-Motility-and-ppat.1002603.s002.ogv 5.0 s, 1,392 × 1,040; 3.22 MB
  
• Multiple-Peptidoglycan-Modification-Networks-Modulate-Helicobacter-pylori's-Cell-Shape-Motility-and-ppat.1002603.s003.ogv 5.0 s, 1,392 × 1,040; 880 KB
  
• Mycobacterium-tuberculosis-Proteins-Involved-in-Mycolic-Acid-Synthesis-and-Transport-Localize-pone.0097148.s009.ogv 16 s, 1,800 × 750; 290 KB
  
• Mycobacterium-tuberculosis-Proteins-Involved-in-Mycolic-Acid-Synthesis-and-Transport-Localize-pone.0097148.s010.ogv 17 s, 1,800 × 750; 406 KB
  
• Mycobacterium-tuberculosis-Proteins-Involved-in-Mycolic-Acid-Synthesis-and-Transport-Localize-pone.0097148.s013.ogv 20 s, 1,800 × 750; 308 KB
  
• Mycobacterium-tuberculosis-Proteins-Involved-in-Mycolic-Acid-Synthesis-and-Transport-Localize-pone.0097148.s018.ogv 15 s, 1,500 × 600; 371 KB
  
• Penicillin-Induced-Persistence-in-Chlamydia-trachomatis-High-Quality-Time-Lapse-Video-Analysis-of-pone.0007723.s002.ogv 3 min 11 s, 480 × 360; 28.36 MB
  
• Penicillin-Induced-Persistence-in-Chlamydia-trachomatis-High-Quality-Time-Lapse-Video-Analysis-of-pone.0007723.s003.ogv 1 min 31 s, 480 × 360; 36.69 MB
  
• Penicillin-Induced-Persistence-in-Chlamydia-trachomatis-High-Quality-Time-Lapse-Video-Analysis-of-pone.0007723.s004.ogv 2 min 24 s, 480 × 360; 20.12 MB
  
• Polar-Localization-of-a-Tripartite-Complex-of-the-Two-Component-System-DcuSDcuR-and-the-Transporter-pone.0115534.s009.ogv 0.7 s, 424 × 348; 508 KB
  
• Polar-Localization-of-a-Tripartite-Complex-of-the-Two-Component-System-DcuSDcuR-and-the-Transporter-pone.0115534.s010.ogv 3.8 s, 508 × 232; 1.07 MB
  
• Pre-Disposition-and-Epigenetics-Govern-Variation-in-Bacterial-Survival-upon-Stress-pgen.1003148.s021.ogv 11 s, 832 × 514; 188 KB
  
• Pre-Disposition-and-Epigenetics-Govern-Variation-in-Bacterial-Survival-upon-Stress-pgen.1003148.s022.ogv 12 s, 924 × 565; 1.05 MB
  
• Pre-Disposition-and-Epigenetics-Govern-Variation-in-Bacterial-Survival-upon-Stress-pgen.1003148.s023.ogv 10 s, 605 × 601; 533 KB
  
• Quantitative-Image-Analysis-and-Modeling-Indicate-the-Agrobacterium-tumefaciens-Type-IV-Secretion-pone.0042219.s002.ogv 18 s, 128 × 124; 99 KB
  
• Quantitative-Image-Analysis-and-Modeling-Indicate-the-Agrobacterium-tumefaciens-Type-IV-Secretion-pone.0042219.s003.ogv 18 s, 128 × 144; 53 KB
  
• 
  Quatrinhsinhtonghopphb.png 528 × 1,740; 40 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s001.ogv 22 s, 480 × 320; 243 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s002.ogv 22 s, 480 × 320; 351 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s003.ogv 16 s, 480 × 320; 212 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s004.ogv 22 s, 480 × 320; 266 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s005.ogv 27 s, 480 × 320; 933 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s006.ogv 23 s, 480 × 320; 335 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s007.ogv 19 s, 480 × 320; 287 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s008.ogv 19 s, 480 × 320; 246 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s009.ogv 16 s, 480 × 320; 302 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s010.ogv 22 s, 480 × 320; 172 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s011.ogv 27 s, 480 × 320; 699 KB
  
• Quorum-Sensing-Controls-Flagellar-Morphogenesis-in-Burkholderia-glumae-pone.0084831.s012.ogv 23 s, 480 × 320; 250 KB
  
• Quorum-Sensing-Desynchronization-Leads-to-Bimodality-and-Patterned-Behaviors-pcbi.1004781.s011.ogv 30 s, 1,280 × 720; 2.3 MB
  
• Quorum-Sensing-Desynchronization-Leads-to-Bimodality-and-Patterned-Behaviors-pcbi.1004781.s012.ogv 30 s, 1,280 × 720; 1.59 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv001.ogv 2 min 25 s, 240 × 240; 384 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv002.ogv 2 min 25 s, 200 × 200; 451 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv003.ogv 2 min 25 s, 240 × 240; 249 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv004.ogv 2 min 25 s, 240 × 240; 256 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv005.ogv 2 min 25 s, 200 × 200; 226 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv006.ogv 2 min 25 s, 240 × 240; 151 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv007.ogv 2 min 25 s, 240 × 240; 220 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv008.ogv 2 min 25 s, 240 × 240; 137 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv009.ogv 33 s, 500 × 500; 4.75 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv010.ogv 33 s, 500 × 500; 5.01 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv011.ogv 1 min 6 s, 240 × 240; 3.17 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv012.ogv 33 s, 500 × 500; 1.52 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv013.ogv 33 s, 500 × 500; 2.59 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv014.ogv 33 s, 500 × 500; 2.42 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv015.ogv 33 s, 500 × 500; 2.31 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv016.ogv 20 s, 240 × 240; 1.47 MB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv017.ogv 13 s, 400 × 400; 226 KB
  
• Self-Organization-in-High-Density-Bacterial-Colonies-Efficient-Crowd-Control-pbio.0050302.sv018.ogv 9.2 s, 400 × 400; 4.55 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s005.ogv 44 s, 362 × 272; 4.23 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s006.ogv 34 s, 362 × 272; 3.5 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s007.ogv 26 s, 362 × 272; 2.31 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s008.ogv 34 s, 362 × 272; 3.16 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s009.ogv 37 s, 362 × 272; 3.45 MB
  
• Smart-Swarms-of-Bacteria-Inspired-Agents-with-Performance-Adaptable-Interactions-pcbi.1002177.s010.ogv 24 s, 362 × 272; 2.18 MB
  
• Swimming-Using-Surface-Acoustic-Waves-pone.0042686.s002.ogv 33 s, 616 × 400; 4.24 MB
  
• The-Bacterium-Endosymbiont-of-Crithidia-deanei-Undergoes-Coordinated-Division-with-the-Host-Cell-pone.0012415.s001.ogv 1.4 s, 320 × 240; 152 KB
  
• The-Bacterium-Endosymbiont-of-Crithidia-deanei-Undergoes-Coordinated-Division-with-the-Host-Cell-pone.0012415.s002.ogv 24 s, 654 × 480; 902 KB
  
• The-Bacterium-Endosymbiont-of-Crithidia-deanei-Undergoes-Coordinated-Division-with-the-Host-Cell-pone.0012415.s003.ogv 24 s, 654 × 480; 1.31 MB
  
• The-Cyst-Dividing-Bacterium-Ramlibacter-tataouinensis-TTB310-Genome-Reveals-a-Well-Stocked-Toolbox-pone.0023784.s014.ogv 8.0 s, 137 × 138; 204 KB