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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Calvin cycle illustration
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Calvin cycle illustration
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Calvin cycle illustration
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ATP-ADP cycle illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
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ATP Computer graphic representation of a molecule of adenosine triphosphate (ATP) The molecule acts as an intracellular battery of metabolic energy
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ATP-ADP cycle illustration
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ATP-ADP cycle illustration
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ATP molecule illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
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ATP molecule illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
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Adenosine purine nucleoside molecule illustration
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Adenosine purine nucleoside molecule illustration
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Adenosine purine nucleoside molecule illustration
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Adenosine purine nucleoside molecule illustration
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Glutamyl-tRNA synthetase from Plasmodium falciparum (PfERS) complexed with ADP molecular model The image shoes a ribbon representation of glutamyl-t
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Computer graphics representation of the ATP- binding domain (reaction site) of phosphoglycerate kinase a glycolytic enzyme (catalyst) In glycolysis
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Glutamyl-tRNA synthetase from Plasmodium falciparum (PfERS) complexed with ADP molecular model The image shoes a ribbon representation of glutamyl-t
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Aerobic respiration and anaerobic fermentation illustration
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Aerobic respiration and anaerobic fermentation illustration
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Electron transport chain redox potentials illustration
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Illustration of the proteins involved in oxidative phosphorylation in the mitochondrial membrane Oxidative phosphorylation produces energy in the fo
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Illustration showing the metabolic pathways of lactic fermentation a type of anaerobic respiration The first stage is glycolysis which produces pyr
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Alcoholic fermentation illustration
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Anaerobic respiration illustration
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Aerobic respiration illustration
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Computer graphics of the enzyme phosphofructo- kinase binding to its substrate fructose-6- phosphate cofactor ATP and effector ADP This enzyme is i
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Photosynthesis illustration
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Cardiac muscle complex illustration
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Cardiac muscle complex illustration
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Illustration of danger-associated molecular patterns (DAMPs) and pathogen-associated molecular patterns (PAMPs) leading to the activation of the NLRP3
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Illustration of danger-associated molecular patterns (DAMPs) and pathogen-associated molecular patterns (PAMPs) leading to the activation of the NLRP3
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NLRP3 inflammasome molecular model
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NLRP3 inflammasome molecular model
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Adenosine triphosphate (ATP) molecule illustration This coenzyme molecule is key to intracellular metabolic energy transfer as it is able to store
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Adenosine triphosphate (ATP) molecule illustration This coenzyme molecule is key to intracellular metabolic energy transfer as it is able to store
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Computer graphics of the enzyme phosphofructo- kinase binding to its substrate fructose-6- phosphate cofactor ATP and effector ADP This enzyme is i
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ATP synthase enzyme complex illustration
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GSK3B enzyme complex with ADP and inhibitor Illustration of the GSK3B enzyme (blue) complexed with molecules of adenosine diphosphate (ADP) and the k
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GSK3B enzyme complex with ADP and inhibitor illustration
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Illustration of mitochondria with an inset showing two types of membrane protein found in the inner membrane (pink) of a mitochondrion Mitochondrial
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Mitochondrial membrane proteins illustration
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Mitochondrial membrane proteins illustration
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Illustration of two types of membrane protein from the inner membrane (pink) of a mitochondrion Mitochondrial complex I (blue centre) catalyses the
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Kinesin motor protein NCD (Non-Claret Disjunctional) Computer model showing the dimeric structure of the kinesin motor protein NCD with ADP shown in
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Kinesin motor protein NCD (Non-Claret Disjunctional) Computer model showing the dimeric structure of the kinesin motor protein NCD with ADP shown in
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Pilus retraction motor PilT Computer model showing the hexameric structure of the bacterial ATPase PilT required for pilus retraction and surface mot
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Pilus retraction motor PilT Computer model showing the hexameric structure of the bacterial ATPase PilT required for pilus retraction and surface mot
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Mitochondrial ADP-ATP-carrier complex Computer model showing a bovine mitochondrial ADP-ATP carrier (green) complexed with inhibitor carboyatractylos
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Mitochondrial ADP-ATP-carrier complex Computer model showing a bovine mitochondrial ADP-ATP carrier (green) complexed with inhibitor carboyatractylos
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P97 ATPase molecule Computer model showing human P97 hexameric ATPase (yellow-green cyan) with complexed ATP (orange) ATPase is an important enzyme
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P97 ATPase molecule Computer model showing human P97 hexameric ATPase (magenta green) with complexed ATP (yellow grey) ATPase is an important enzy
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Replicative DNA (deoxyribonucleic acid) helicase molecule Computer model showing the structure of a hexameric bacterial replicative DNA helicase (bro
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Replicative DNA (deoxyribonucleic acid) helicase molecule Computer model showing the structure of a hexameric bacterial replicative DNA helicase (mag
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V-type proton ATPase Computer model showing the subunit structure of yeast eukaryotic V-ATPase ATPase is an important enzyme that provides energy fo
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V-type proton ATPase Computer model showing the subunit structure of yeast eukaryotic V-ATPase ATPase is an important enzyme that provides energy fo
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Essential endoplasmic reticulum chaperone GRP94 with ADP bound Computer model showing the structure of the chaperone protein GRP94 (blue pink) with
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Essential endoplasmic reticulum chaperone GRP94 with ADP bound Computer model showing the structure of the chaperone protein GRP94 (blue pink) with
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Bacterial ATPase complex Computer model showing the structure of the F-ATPase delta subunit (blue) complexed with the alpha subunit (pink) ATPase is
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Bacterial ATPase complex Computer model showing the structure of the F-ATPase delta subunit (red) complexed with the alpha subunit (green) ATPase is
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Human PAPS synthetase complex Computer model showing the structure of human PAPS synthetase with the fused chains A (purple) and B (red) ADP (yellow
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Human PAPS synthetase complex
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Phosphotransferase complex Computer model showing the structure of phosphotransferase type IIIa (green) complexed with ADP (orange) and kanamycin A (
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Phosphotransferase complex Computer model showing the structure of phosphotransferase type IIIa (pale blue-beige) complexed with ADP (red) and kanamy
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Bacterial ATP synthase (ATPase) stalk structure Computer model showing the structure of the b subunit dimerization domain the stalk or stator Atoms
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Bacterial ATP synthase (ATPase) stalk structure Computer model showing the structure of the b subunit dimerization domain the stalk or stator Atoms
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Glutamine synthetase molecule Computer model showing the structure of bacterial glutamine synthetase composed of 12 identical subunits (pink cyan)
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Glutamine synthetase molecule Computer model showing the structure of bacterial glutamine synthetase composed of 12 identical subunits (pink cyan)
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Chaperone GRPE complex Computer model showing the structure of the nucleotide exchange factor GRPE (blue red) complexed with the ATPase domain of th
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Chaperone GRPE complex Computer model showing the structure of the nucleotide exchange factor GRPE (blue red) complexed with the ATPase domain of th
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ATP synthase rotor ring Molecular model showing the rotor ring component of ATP synthase an important enzyme that provides energy for cells through
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ATP synthase rotor ring Molecular model showing the rotor ring component of ATP synthase an important enzyme that provides energy for cells through
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CAM daytime photosynthesis Illustration of the daytime mechanism for crassulacean acid metabolism (CAM) photosynthesis used by some plants to obtain
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CAM daytime photosynthesis Illustration of the daytime mechanism for crassulacean acid metabolism (CAM) photosynthesis used by some plants to obtain
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Photosynthesis electron transport complex Illustration of cyclic electron transport taking place as part of Photosystem I in photosynthesis on the th
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Photosynthesis electron transport complex Illustration of cyclic electron transport taking place as part of Photosystem I in photosynthesis on the th
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Photosynthesis photosystems Illustration of Photosystem I (right) and Photosystem II (left) complexes of multiple proteins that react to transfer en
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Photosynthesis photosystems Illustration of Photosystem I (right) and Photosystem II (left) complexes of multiple proteins that react to transfer en
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Photosynthesis metabolism Illustration of the reactions that take place in the thylakoid stacks (centre right) in a plants chloroplast during photos
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Photosynthesis metabolism Illustration of the reactions that take place in the thylakoid stacks (centre right) in a plants chloroplast during photos
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ATP synthase enzyme complex Illustration of the enzyme complex that drives the synthesis of the energy-carrying molecule ATP (adenosine triphosphate)
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ATP synthase enzyme complex Illustration of the enzyme complex that drives the synthesis of the energy-carrying molecule ATP (adenosine triphosphate)
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Electron transport system illustration
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Electron transport system illustration
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Na-K membrane ion pump Illustration of the Na-K-ATPase pump (red) transporting ions across a cell membrane (light blue) At left the pump binds to t
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Na-K membrane ion pump Illustration of the Na-K-ATPase pump (red) transporting ions across a cell membrane (light blue) At left the pump binds to t
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Na-K membrane ion pump Illustration of how sodium (Na) and potassium (K) ions are pumped through a channel (red) in a cell membrane (blue) The cel
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Na-K membrane ion pump Illustration of how sodium (Na) and potassium (K) ions are pumped through a channel (red) in a cell membrane (blue) The cel
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Krebs metabolic cycle
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Calvin-Benson metabolic cycle
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ATPase molecule Computer model showing the structure of the catalytic F1 unit of an ATP synthase (ATPase) molecule from a rat mitochondrion ATPase i
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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Glycolysis illustration
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Calvin cycle illustration
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