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- https://bio.libretexts.org/Learning_Objects/Visualizations_and_Simulations/Molecular_and_Protein_Interactive_Figures/Caffeine_(GLmol)/Testing
- https://bio.libretexts.org/Courses/Wheaton_College_Massachusetts/Principles_of_Biochemistry/08%3A_Carbohydrate_structure_and_metabolism/8.01%3A_Carbohydrates_overviewThe chemical formula for glucose and galactose is C 6 H 12 O 6 ; both are hexoses, but the arrangements of the hydrogens and hydroxyl groups are different at position C 4 . Because of this small diffe...The chemical formula for glucose and galactose is C 6 H 12 O 6 ; both are hexoses, but the arrangements of the hydrogens and hydroxyl groups are different at position C 4 . Because of this small difference, they differ structurally and chemically and are known as chemical isomers because of the different arrangement of functional groups around the asymmetric carbon; both
- https://bio.libretexts.org/Learning_Objects/Visualizations_and_Simulations/Molecular_and_Protein_Interactive_Figures/GLmol_3Dmol_and_JSmol_multiple
- https://bio.libretexts.org/Courses/Roosevelt_University/BCHM_355_455_Biochemistry_(Roosevelt_University)/04%3A_Proteins-_Structure_and_Folding/4.07%3A_The_Three-Dimensional_Structure_of_Proteins/4.7.06%3A_Intrinsically_Disordered_ProteinsFigure \(\PageIndex{9}\) below shows a simplified molecular dynamics simulation of the intrinsically disordered protein human alpha-synuclein (Uniprot ID P37840). (Molecular dynamics were discussed in...Figure \(\PageIndex{9}\) below shows a simplified molecular dynamics simulation of the intrinsically disordered protein human alpha-synuclein (Uniprot ID P37840). (Molecular dynamics were discussed in Chapter 3.4: Analyses of Protein Structure.) α-Synuclein (140 amino acids, MW 14,460) is expressed in the brain and presynaptic terminals in the central nervous system but also in more distal neurons and is involved in the regulation of neurotransmitter release and in the synaptic vesicles that ho…
- https://bio.libretexts.org/Learning_Objects/Visualizations_and_Simulations/Molecular_and_Protein_Interactive_Figures/Examples_(all_three_systems)
- https://bio.libretexts.org/Workbench/Biochem_Remix_Acevedo/04%3A_The_Three-Dimensional_Structure_of_Proteins/4.02%3A_Tertiary_and_Quaternary_StructuresProteins, especially those involved in cytoskeletal filaments, can form fibers with helical symmetry which differs from those described above since the monomers at the ends of helical fibers, although...Proteins, especially those involved in cytoskeletal filaments, can form fibers with helical symmetry which differs from those described above since the monomers at the ends of helical fibers, although they have the same tertiary structures as those in the middle of the helical fibers, do not contact the same number of monomers as monomers internal in the oligomer.
- https://bio.libretexts.org/Workbench/Biochem_Remix_Acevedo/04%3A_The_Three-Dimensional_Structure_of_Proteins/4.04%3A_Protein_with_Alpha_Alpha-Beta_Beta_and_Little_Secondary_StructureProteins can also be classified as to the type and extent of secondary structure found in the protein. Example: the Z[beta] Domain of the RNA-editing Enzyme ADAR1 (1xmk), shown in the interactive iCn3...Proteins can also be classified as to the type and extent of secondary structure found in the protein. Example: the Z[beta] Domain of the RNA-editing Enzyme ADAR1 (1xmk), shown in the interactive iCn3D model in Figure \(\PageIndex{1}\). Example: The second SH3 domain from ponsin (2O9S), shown in the interactive iCn3D model in Figure \(\PageIndex{3}\). Example: Human biliverdin IX beta reductase (1hdo), shown in the interactive iCn3D model in Figure \(\PageIndex{6}\).
- https://bio.libretexts.org/Bookshelves/Biochemistry/Fundamentals_of_Biochemistry_(Jakubowski_and_Flatt)/01%3A_Unit_I-_Structure_and_Catalysis/04%3A_The_Three-Dimensional_Structure_of_Proteins/4.07%3A_Fibrillar_ProteinsThe page discusses various fibrillar proteins, focusing on their structure, function, and role in biological systems. It describes different types of fibrillar proteins, such as collagen, ??-keratin, ...The page discusses various fibrillar proteins, focusing on their structure, function, and role in biological systems. It describes different types of fibrillar proteins, such as collagen, ??-keratin, elastin, and fibrinogen, and highlights their structural characteristics, including unique amino acid compositions and hierarchical organizations.
- https://bio.libretexts.org/Learning_Objects/Visualizations_and_Simulations/Molecular_and_Protein_Interactive_Figures/Caffeine_(GLmol)
- https://bio.libretexts.org/Workbench/PULSE%3A_Midwest_and_Great_Plains_Region_Workshop_2021/Creative_Problem_Solving_MaterialsCreating Problem Solving Toolkit Toolkit Link Pre-Workshop Readings Treffinger's piece on CPS Asai, Race Matters Resources on creative problem solving and negotiation Problem Solving in Conflict Resol...Creating Problem Solving Toolkit Toolkit Link Pre-Workshop Readings Treffinger's piece on CPS Asai, Race Matters Resources on creative problem solving and negotiation Problem Solving in Conflict Resolution (Weitzman) CPS tools: ladder of abstraction; webbing; if-then CPS tool: Time Line CPS tools: brainwrite (divergent thinking) and cluster-combine-clarify-cull-choose (convergent thinking) CPS guide
- https://bio.libretexts.org/Courses/Clinton_College/BIO_300%3A_Introduction_to_Genetics_(Neely)/01%3A_Chemistry_to_Chromosomes/1.01%3A__The_Structure_of_DNAFigure \(\PageIndex{2}\):Watson and Crick proposed the double helix model for DNA. (a) The sugar-phosphate backbones are on the outside of the double helix and purines and pyrimidines form the “rungs”...Figure \(\PageIndex{2}\):Watson and Crick proposed the double helix model for DNA. (a) The sugar-phosphate backbones are on the outside of the double helix and purines and pyrimidines form the “rungs” of the DNA helix ladder. (b) The two DNA strands are antiparallel to each other. (c) The direction of each strand is identified by numbering the carbons (1 through 5) in each sugar molecule.
