Tertiary structure molecular model

In order to represent 3D molecular models it is necessary to supply structure files with 3D information (e.g., pdb, xyz, df, mol, etc.. If structures from a structure editor are used directly, the files do not normally include 3D data. Indusion of such data can be achieved only via 3D structure generators, force-field calculations, etc. 3D structures can then be represented in various display modes, e.g., wire frame, balls and sticks, space-filling (see Section 2.11). Proteins are visualized by various representations of helices, / -strains, or tertiary structures. An additional feature is the ability to color the atoms according to subunits, temperature, or chain types. During all such operations the molecule can be interactively moved, rotated, or zoomed by the user. 

Mosimann S, S Meleshko and M N G Jones 1995. A Critical Assessment of Comparative Molecular Modeling of Tertiary Structures of Proteins. Proteins Structure, Function and Genetics 23 301-317. 

Model optimization is a further refinement of the secondary and tertiary structure. At a minimum, a molecular mechanics energy minimization is done. Often, molecular dynamics or simulated annealing are used. These are frequently chosen to search the region of conformational space relatively close to the starting structure. For marginal cases, this step is very important and larger simulations should be run. 

Wnte structural formulas or build molecular models for all the constitutionally isomenc alcohols of molecular formula C5H12O Assign a substitutive and a functional class name to each one and specify whether it is a pnmary secondary or tertiary alcohol... 

MI Sutcliffe, CM Dobson, RE Oswald. Solution structure of neuronal bungarotoxm determined by two-dimensional NMR spectroscopy Calculation of tertiary structure using systematic homologous model building, dynamical simulated annealing, and restrained molecular dynamics. Biochemistry 31 2962-2970, 1992. 

S Mosimann, R Meleshko, MNG lames. A critical assessment of comparative molecular modeling of tertiary structures of proteins. Proteins 23 301-317, 1995. 

Write structural formulas or build molecular models for all the amines of molecular formula C4H11N. Give an acceptable name for each one, and classify it as a primary, secondary, or tertiary amine. 

In an attempt to separate the domains from the cores, we used limited degradation with several proteases. CBH I (65 kda) and CBH II (58 kda) under native conditions could only be cleaved successfully with papain (15). The cores (56 and 45 kda) and terminal peptides (11 and 13 kda) were isolated by affinity chromatography (15,16) and the scission points were determined unequivocally. The effect on the activity of these enzymes was quite remarkable (Fig. 7). The cores remained perfectly active towards soluble substrates such as those described above. They exhibited, however, a considerably decreased activity towards native (microcrystalline) cellulose. These effects could be attributed to the loss of the terminal peptides, which were recognized as binding domains, whose role is to raise the relative concentration of the intact enzymes on the cellulose surface. This aspect is discussed further below. The tertiary structures of the intact CBH I and its core in solution were examined by small angle X-ray scattering (SAXS) analysis (17,18). The molecular parameters derived for the core (Rj = 2.09 mm, Dmax = 6.5 nm) and for the intact CBH I (R = 4.27 nm, Dmax = 18 nm) indicated very different shapes for both enzymes. Models constructed on the basis of these SAXS measurements showed a tadpole structure for the intact enzyme and an isotropic ellipsoid for the core (Fig. 8). The extended, flexible tail part of the tadpole should thus be identified with the C-terminal peptide of CBH I. 

Tsakovska [194] used methods of molecular modeling to investigate a group of 25 phenothiazines and structurally related compounds. The role of hydrophobicity of modulators and hydrogen-bond acceptor interactions in MDR reversal were revealed. The piperazine moiety with a tertiary nitrogen was identified as the most favorable type of side chain for effective MDR modulators. 

Chirality Isomerism Lewis Structures Magnetism Molecular Geometry Molecular Modeling Molecular Structure Molecules Periodic Table Primary Structure Quaternary Structure Secondary Structure Stoichiometry Tertiary Structure... 

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