Proteins irregularities

One important class of integral equation theories is based on the reference interaction site model (RISM) proposed by Chandler [77]. These RISM theories have been used to smdy the confonnation of small peptides in liquid water [78-80]. However, the approach is not appropriate for large molecular solutes such as proteins and nucleic acids. Because RISM is based on a reduction to site-site, solute-solvent radially symmetrical distribution functions, there is a loss of infonnation about the tliree-dimensional spatial organization of the solvent density around a macromolecular solute of irregular shape. To circumvent this limitation, extensions of RISM-like theories for tliree-dimensional space (3d-RISM) have been proposed [81,82],... 

In retrospect it is easy to see that such structural irregularity is actually required for proteins to fulfill their diverse functions. Information storage and transfer from DNA is essentially linear, and DNA molecules of very different information content can therefore have essentially the same gross structure. In contrast, proteins must recognize many thousands of different molecules in the cell by detailed three-dimensional interactions, which... 

Proteins are usually separated into two distinct functional classes passive structural materials, which are built up from long fibers, and active components of cellular machinery in which the protein chains are arranged in small compact domains, as we have discussed in earlier chapters. In spite of their differences in structure and function, both these classes of proteins contain a helices and/or p sheets separated by regions of irregular structure. In most cases the fibrous proteins contain specific repetitive amino acid sequences that are necessary for their specific three-dimensional structure. 

This asymmetry can be partially attributed to the irregular distribution of proteins within the membranes. An inside-outside asymmetry is also provided by the external location of the carbohydrates attached to membrane proteins. In addition, specific enzymes are lo-... 

Numerous organisms, both marine and terrestrial, produce protein toxins. These are typically relatively small, and rich in disulfide crosslinks. Since they are often difficult to crystallize, relatively few structures from this class of proteins are known. In the past five years two dimensional NMR methods have developed to the point where they can be used to determine the solution structures of small proteins and nucleic acids. We have analyzed the structures of toxins II and III of RadiarUhus paumotensis using this approach. We find that the dominant structure is )9-sheet, with the strands connected by loops of irregular structure. Most of the residues which have been determined to be important for toxicity are contained in one of the loops. The general methods used for structure analysis will be described, and the structures of the toxins RpII and RpIII will be discussed and compared with homologous toxins from other anemone species. 

Although the ROA spectra of typical /1-sheet proteins share some of the features observed in /3-sheet poly-L-lysine, there are also some differences, especially in the amide I region. This is because the /1-sheet in proteins tends to be twisted and irregular, whereas that in polypeptides tends to be extended, multistranded and relatively flat. 

---