Detail homology

An additional notable resource details homology relationships between human, mouse, and rat. Derived from a high-resolution RH maps, homologies for over 500 genes have been identified and are available in tabular format at a user-friendly Web site (Watanabe et al., 1999). 

What can be done by predictive methods if the sequence search fails to reveal any homology with a protein of known tertiary structure Is it possible to model a tertiary structure from the amino acid sequence alone There are no methods available today to do this and obtain a model detailed enough to be of any use, for example, in drug design and protein engineering. This is, however, a very active area of research and quite promising results are being obtained in some cases it is possible to predict correctly the type of protein, a, p, or a/p, and even to derive approximations to the correct fold. 

Finally, in connection with the investigations on the antineuritic action of homologs and analogs of vitamin Bi, the corresponding seleno compound was also mentioned. However, no details are given on the properties (except mp 203°C) and method of synthesis of this compound. 

More detailed aspects of protein function can be obtained also by force-field based approaches. Whereas protein function requires protein dynamics, no experimental technique can observe it directly on an atomic scale, and motions have to be simulated by molecular dynamics (MD) simulations. Also free energy differences (e.g. between binding energies of different protein ligands) can be characterised by MD simulations. Molecular mechanics or molecular dynamics based approaches are also necessary for homology modelling and for structure refinement in X-ray crystallography and NMR structure determination. 

For a more detailed description or modeling of the surfactant properties of the alkanesulfonates it is necessary to use individual, well-defined compounds typical of the technical mixtures. Recently, new data were obtained from a series of individual homologous alkanesulfonates in which the positions of the functional group and the cations vary [38]. 

Primary structure analysis of phenylphosphate carboxylase of T. aromatica is performed in detail, to clarify the reaction mechanism involving four kinds of subunits. The a, (3, y, 8 subunits have molecular masses of 54, 53, 18, and lOkDa, respectively, which make up the active phenylphosphate carboxylase. The primary structures of a and (3 subunits show homology with 3-octaprenyl-4-hydroxybenzoate decarboxylase, 4-hydroxybenzoate decarboxylase, and vanil-late decarboxylase, whereas y subunit is unique and not characterized. The 18kDa 8 subunit belongs to a hydratase/phosphatase protein family. Taking 4-hydroxybenzoate decarboxylase into consideration, Schiihle and Fuchs postulate that the a(3y core enzyme catalyzes the reversible carboxylation. ... 

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